#pragma once

#include <limits>
#include <map>
#include <memory>
#include <optional>
#include <set>
#include <string>
#include <string_view>
#include <tuple>
#include <type_traits>
#include <unordered_map>
#include <unordered_set>
#include <utility>
#include <vector>

#include "drake/common/default_scalars.h"
#include "drake/common/nice_type_name.h"
#include "drake/common/random.h"
#include "drake/geometry/scene_graph.h"
#include "drake/math/rigid_transform.h"
#include "drake/multibody/contact_solvers/contact_solver_results.h"
#include "drake/multibody/plant/constraint_specs.h"
#include "drake/multibody/plant/contact_results.h"
#include "drake/multibody/plant/coulomb_friction.h"
#include "drake/multibody/plant/discrete_update_manager.h"
#include "drake/multibody/plant/multibody_plant_config.h"
#include "drake/multibody/plant/physical_model.h"
#include "drake/multibody/topology/multibody_graph.h"
#include "drake/multibody/tree/force_element.h"
#include "drake/multibody/tree/multibody_tree-inl.h"
#include "drake/multibody/tree/multibody_tree_system.h"
#include "drake/multibody/tree/rigid_body.h"
#include "drake/multibody/tree/weld_joint.h"
#include "drake/systems/framework/diagram_builder.h"
#include "drake/systems/framework/leaf_system.h"
#include "drake/systems/framework/scalar_conversion_traits.h"

namespace drake {
namespace multibody {
namespace internal {

// Data stored in the cache entry for the hydroelastic with fallback contact
// model.
template <typename T>
struct HydroelasticFallbackCacheData {
  std::vector<geometry::ContactSurface<T>> contact_surfaces;
  std::vector<geometry::PenetrationAsPointPair<T>> point_pairs;
};

// Structure used in the calculation of hydroelastic contact forces.
template <typename T>
struct HydroelasticContactInfoAndBodySpatialForces {
  explicit HydroelasticContactInfoAndBodySpatialForces(int num_bodies) {
    F_BBo_W_array.resize(num_bodies);
  }

  // Forces from hydroelastic contact applied to the origin of each body
  // (indexed by BodyNodeIndex) in the MultibodyPlant.
  std::vector<SpatialForce<T>> F_BBo_W_array;

  // Information used for contact reporting collected through the evaluation
  // of the hydroelastic model.
  std::vector<HydroelasticContactInfo<T>> contact_info;
};

// Data stored in the cache entry for joint locking.
template <typename T>
struct JointLockingCacheData {
  // @name Dense joint locking indices.
  // Values of each will be a sorted subset of [0, num_velocities()].
  // `unlocked_velocity_indices` and `locked_velocity_indices` are disjoint and
  // their union is [0, num_velocities()].
  // @{
  // Stores indices of unlocked DoFs in the context.
  std::vector<int> unlocked_velocity_indices;
  // Stores indices of locked DoFs in the context.
  std::vector<int> locked_velocity_indices;
  // @}

  // @name Per-tree joint locking indices.
  // Each has the same size as the number of trees in the plant's topology and
  // is resized accordingly on output. For both unlocked and locked, element i
  // is a sorted subset of [0, tree_i.num_velocities()] where tree_i is the i-th
  // tree in this plant's topology. They are likewise disjoint and their union
  // is [0, tree_i.num_velocities()].
  // @{
  // Stores indices of unlocked DoFs per tree in the plant's topology.
  std::vector<std::vector<int>> unlocked_velocity_indices_per_tree;
  // Stores indices of locked DoFs per tree in the plant's topology.
  std::vector<std::vector<int>> locked_velocity_indices_per_tree;
  // @}
};

// Wrapper struct for using std::map<MultibodyConstraintId, bool> as a Value
// type for an abstract parameter.
struct ConstraintActiveStatusMap {
  std::map<MultibodyConstraintId, bool> map;
};

// This struct contains the parameters to compute forces to enforce
// no-interpenetration between bodies by a penalty method.
struct ContactByPenaltyMethodParameters {
  DRAKE_DEFAULT_COPY_AND_MOVE_AND_ASSIGN(ContactByPenaltyMethodParameters);

  ContactByPenaltyMethodParameters() = default;

  // Penalty method coefficients used to compute contact forces.
  double geometry_stiffness{0};
  double dissipation{0};
  // TODO(xuchenhan-tri): Consider using std::optional instead of an illegal
  //  value as a flag.
  // An estimated time scale in which objects come to a relative stop during
  // contact.
  double time_scale{-1.0};
  // Acceleration of gravity in the model. Used to estimate penalty method
  // constants from a static equilibrium analysis.
  std::optional<double> gravity;
};

// Forward declaration.
template <typename>
class MultibodyPlantModelAttorney;
template <typename>
class MultibodyPlantDiscreteUpdateManagerAttorney;

}  // namespace internal

// TODO(amcastro-tri): Add a section on contact models in
// contact_model_doxygen.h.
/// Enumeration for contact model options.
enum class ContactModel {
  /// Contact forces are computed using the Hydroelastic model. Contact between
  /// unsupported geometries will cause a runtime exception.
  kHydroelastic,

  /// Contact forces are computed using a point contact model, see @ref
  /// point_contact_approximation "Numerical Approximation of Point Contact".
  kPoint,

  /// Contact forces are computed using the hydroelastic model, where possible.
  /// For most other unsupported colliding pairs, the point model from
  /// kPoint is used. See
  /// geometry::QueryObject::ComputeContactSurfacesWithFallback for more
  /// details.
  kHydroelasticWithFallback,

  /// Legacy alias. TODO(jwnimmer-tri) Deprecate this constant.
  kHydroelasticsOnly = kHydroelastic,
  /// Legacy alias. TODO(jwnimmer-tri) Deprecate this constant.
  kPointContactOnly = kPoint,
};

/// The type of the contact solver used for a discrete MultibodyPlant model.
///
/// Note: the SAP solver only fully supports scalar type `double`. For
/// scalar type `AutoDiffXd`, the SAP solver throws if any constraint (including
/// contact) is detected. As a consequence, one can only run dynamic simulations
/// without any constraints under the combination of SAP and `AutoDiffXd`. The
/// SAP solver does not support symbolic calculations.
///
/// <h2>References</h2>
///
/// - [Castro et al., 2019] Castro, A.M, Qu, A., Kuppuswamy, N., Alspach, A.,
///   Sherman, M.A., 2019. A Transition-Aware Method for the Simulation of
///   Compliant Contact with Regularized Friction. Available online at
///   https://arxiv.org/abs/1909.05700.
/// - [Castro et al., 2022] Castro A., Permenter F. and Han X., 2022. An
///   Unconstrained Convex Formulation of Compliant Contact. Available online at
///   https://arxiv.org/abs/2110.10107.
enum class DiscreteContactSolver {
  /// TAMSI solver, see [Castro et al., 2019].
  kTamsi,
  /// SAP solver, see [Castro et al., 2022].
  kSap,
};

/// @cond
// Helper macro to throw an exception within methods that should not be called
// post-finalize.
#define DRAKE_MBP_THROW_IF_FINALIZED() ThrowIfFinalized(__func__)

// Helper macro to throw an exception within methods that should not be called
// pre-finalize.
#define DRAKE_MBP_THROW_IF_NOT_FINALIZED() ThrowIfNotFinalized(__func__)
/// @endcond

/**
%MultibodyPlant is a Drake system framework representation (see
systems::System) for the model of a physical system consisting of a
collection of interconnected bodies.  See @ref multibody for an overview of
concepts/notation.

@system
name: MultibodyPlant
input_ports:
- actuation
- applied_generalized_force
- applied_spatial_force
- <em style="color:gray">model_instance_name[i]</em>_actuation
- <em style="color:gray">model_instance_name[i]</em>_desired_state
- <span style="color:green">geometry_query</span>
output_ports:
- state
- body_poses
- body_spatial_velocities
- body_spatial_accelerations
- generalized_acceleration
- net_actuation
- reaction_forces
- contact_results
- <em style="color:gray">model_instance_name[i]</em>_state
- '<em style="color:gray">
  model_instance_name[i]</em>_generalized_acceleration'
- '<em style="color:gray">
  model_instance_name[i]</em>_generalized_contact_forces'
- <span style="color:green">geometry_pose</span>
@endsystem

The ports whose names begin with <em style="color:gray">
model_instance_name[i]</em> represent groups of ports, one for each of the
@ref model_instances "model instances", with i ∈ {0, ..., N-1} for the N
model instances. If a model instance does not contain any data of the
indicated type the port will still be present but its value will be a
zero-length vector. (Model instances `world_model_instance()` and
`default_model_instance()` always exist.)

The ports shown in <span style="color:green">
green</span> are for communication with Drake's
@ref geometry::SceneGraph "SceneGraph" system for dealing with geometry.

%MultibodyPlant provides a user-facing API for:

- @ref mbp_input_and_output_ports "Ports":
  Access input and output ports.
- @ref mbp_construction "Construction":
  Add bodies, joints, frames, force elements, and actuators.
- @ref mbp_geometry "Geometry":
  Register geometries to a provided SceneGraph instance.
- @ref mbp_contact_modeling "Contact modeling":
  Select and parameterize contact models.
- @ref mbp_state_accessors_and_mutators "State access and modification":
  Obtain and manipulate position and velocity state variables.
- @ref mbp_parameters "Parameters"
  Working with system parameters for various multibody elements.
- @ref mbp_working_with_free_bodies "Free bodies":
  Work conveniently with free (floating) bodies.
- @ref mbp_kinematic_and_dynamic_computations "Kinematics and dynamics":
  Perform @ref systems::Context "Context"-dependent kinematic and dynamic
  queries.
- @ref mbp_system_matrix_computations "System matrices":
  Explicitly form matrices that appear in the equations of motion.
- @ref mbp_introspection "Introspection":
  Perform introspection to find out what's in the %MultibodyPlant.

@anchor model_instances
                        ### Model Instances

A MultiBodyPlant may contain multiple model instances. Each model instance
corresponds to a
set of bodies and their connections (joints). Model instances provide
methods to get or set the state of the set of bodies (e.g., through
GetPositionsAndVelocities() and SetPositionsAndVelocities()), connecting
controllers (through get_state_output_port()
and get_actuation_input_port()), and organizing duplicate models (read
through a parser). In fact, many %MultibodyPlant methods are overloaded
to allow operating on the entire plant or just the subset corresponding to
the model instance; for example, one GetPositions() method obtains the
generalized positions for the entire plant while another GetPositions()
method obtains the generalized positions for model instance.

Model instances are frequently defined through SDFormat files
(using the `model` tag) and are automatically created when SDFormat
files are parsed (by Parser). There are two special
multibody::ModelInstanceIndex values. The world body is always
multibody::ModelInstanceIndex 0. multibody::ModelInstanceIndex 1 is
reserved for all elements with no explicit model instance and
is generally only relevant for elements
created programmatically (and only when a model instance is not explicitly
specified). Note that Parser creates model instances (resulting in a
multibody::ModelInstanceIndex ≥ 2) as needed.

See num_model_instances(),
num_positions(),
num_velocities(), num_actuated_dofs(),
AddModelInstance() GetPositionsAndVelocities(),
GetPositions(), GetVelocities(),
SetPositionsAndVelocities(),
SetPositions(), SetVelocities(),
GetPositionsFromArray(), GetVelocitiesFromArray(),
SetPositionsInArray(), SetVelocitiesInArray(), SetActuationInArray(),
HasModelInstanceNamed(), GetModelInstanceName(),
get_state_output_port(),
get_actuation_input_port().

@anchor mbp_equations_of_motion
                        ### System dynamics

<!-- TODO(amcastro-tri): Update this documentation to include:
     - Bilateral constraints.
     - Unilateral constraints and contact. -->

The state of a multibody system `x = [q; v]` is given by its generalized
positions vector q, of size `nq` (see num_positions()), and by its
generalized velocities vector v, of size `nv` (see num_velocities()).
As a Drake @ref systems::System "System", %MultibodyPlant implements the
governing equations for a
multibody dynamical system in the form `ẋ = f(t, x, u)` with t being
time and u the actuation forces. The governing equations for
the dynamics of a multibody system modeled with %MultibodyPlant are
[Featherstone 2008, Jain 2010]: <pre>
         q̇ = N(q)v
  (1)    M(q)v̇ + C(q, v)v = τ
</pre>
where `M(q)` is the mass matrix of the multibody system (including rigid body
mass properties and @ref reflected_inertia "reflected inertias"), `C(q, v)v`
contains Coriolis, centripetal, and gyroscopic terms and
`N(q)` is the kinematic coupling matrix describing the relationship between
q̇ (the time derivatives of the generalized positions) and the generalized
velocities v, [Seth 2010]. `N(q)` is an `nq x nv` matrix.
The vector `τ ∈ ℝⁿᵛ` on the right hand side of Eq. (1) is
the system's generalized forces. These incorporate gravity, springs,
externally applied body forces, constraint forces, and contact forces.

@anchor mbp_actuation
                ### Actuation

In a %MultibodyPlant model an actuator can be added as a JointActuator, see
AddJointActuator(). The plant declares actuation input ports to provide
feedforward actuation, both for the %MultibodyPlant as a whole (see
get_actuation_input_port()) and for each individual @ref model_instances
"model instance" in the %MultibodyPlant (see
@ref get_actuation_input_port(ModelInstanceIndex)const
"get_actuation_input_port(ModelInstanceIndex)").
Any actuation input ports not connected are assumed to be zero. Actuation values
from the full %MultibodyPlant model port (get_actuation_input_port()) and from
the per model-instance ports (
@ref get_actuation_input_port(ModelInstanceIndex)const
"get_actuation_input_port(ModelInstanceIndex)") are summed up.

@note The vector data supplied to %MultibodyPlant's actuation input ports should
be ordered by @ref JointActuatorIndex. For the get_actuation_input_port() that
covers all actuators, the iᵗʰ vector element corresponds to
`JointActuatorIndex(i)`. For the
@ref get_actuation_input_port(ModelInstanceIndex)const
"get_actuation_input_port(ModelInstanceIndex)" specific to a model index, the
vector data is ordered by monotonically increasing @ref JointActuatorIndex for
the actuators within that model instance: the 0ᵗʰ vector element
corresponds to the lowest-numbered %JointActuatorIndex of that instance, the 1ˢᵗ
vector element corresponds to the second-lowest-numbered %JointActuatorIndex of
that instance, etc.

@note The following snippet shows how per model instance actuation can be set:
```
ModelInstanceIndex model_instance_index = ...;
VectorX<T> u_instance(plant.num_actuated_dofs(model_instance_index));
int offset = 0;
for (JointActuatorIndex joint_actuator_index :
         plant.GetJointActuatorIndices(model_instance_index)) {
  const JointActuator<T>& actuator = plant.get_joint_actuator(
      joint_actuator_index);
  const Joint<T>& joint = actuator.joint();
  VectorX<T> u_joint = ... my_actuation_logic_for(joint) ...;
  ASSERT(u_joint.size() == joint_actuator.num_inputs());
  u_instance.segment(offset, u_joint.size()) = u_joint;
  offset += u_joint.size();
}
plant.get_actuation_input_port(model_instance_index).FixValue(
    plant_context, u_instance);
```

@note To inter-operate between the whole plant actuation vector and sets of
per-model instance actuation vectors, see SetActuationInArray() to gather the
model instance vectors into a whole plant vector and GetActuationFromArray() to
scatter the whole plant vector into per-model instance vectors.

@warning Effort limits (JointActuator::effort_limit()) are not enforced, unless
PD controllers are defined.
See @ref pd_controllers "Using PD controlled actuators".

<!-- TODO(amcastro-tri): Consider enforcing effort limits whether PD controllers
     are defined or not. -->

@anchor pd_controllers
  #### Using PD controlled actuators

While PD controllers can be modeled externally and be connected to the
%MultibodyPlant model via the get_actuation_input_port(), simulation stability
at discrete time steps can be compromised for high controller gains. For such
cases, simulation stability and robustness can be improved significantly by
moving your PD controller into the plant where the discrete solver can strongly
couple controller and model dynamics.

@warning Currently, this feature is only supported for discrete models
(is_discrete() is true) using the SAP solver (get_discrete_contact_solver()
returns DiscreteContactSolver::kSap.)

PD controlled joint actuators can be defined by setting PD gains for each joint
actuator, see JointActuator::set_controller_gains(). Unless these gains are
specified, joint actuators will not be PD controlled and
JointActuator::has_controller() will return `false`.

@warning For PD controlled models, all joint actuators in a model instance are
required to have PD controllers defined. That is, partially PD controlled model
instances are not supported. An exception will be thrown when evaluating the
actuation input ports if only a subset of the actuators in a model instance is
PD controlled.

For models with PD controllers, the actuation torque per actuator is computed
according to: <pre>
  ũ = -Kp⋅(q − qd) - Kd⋅(v − vd) + u_ff
  u = max(−e, min(e, ũ))
</pre>
where qd and vd are desired configuration and velocity (see
get_desired_state_input_port()) for the actuated joint (see
JointActuator::joint()), Kp and Kd are the proportional and derivative gains of
the actuator (see JointActuator::get_controller_gains()), `u_ff` is the
feed-forward actuation specified with get_actuation_input_port(), and `e`
corresponds to effort limit (see JointActuator::effort_limit()).

Notice that actuation through get_actuation_input_port() and PD control are not
mutually exclusive, and they can be used together. This is better explained
through examples:
  1. **PD controlled gripper**. In this case, only PD control is used to drive
     the opening and closing of the fingers. The feed-forward term is assumed to
     be zero and the actuation input port is not required to be connected.
  2. **Robot arm**. A typical configuration consists on applying gravity
     compensation in the feed-forward term plus PD control to drive the robot to
     a given desired state.

@anchor pd_controllers_and_ports
  #### Actuation input ports requirements

The following table specifies whether actuation ports are required to be
connected or not:

|               Port               |   without PD control  | with PD control |
| :------------------------------: | :-------------------: | :-------------: |
|  get_actuation_input_port()      |          yes          |       no¹       |
|  get_desired_state_input_port()  |          no²          |       yes       |

¹ Feed-forward actuation is not required for models with PD controlled
  actuators. This simplifies the diagram wiring for models that only rely on PD
  controllers.

² This port is always declared, though it will be zero sized for model instances
  with no PD controllers.

  #### Net actuation

The total joint actuation applied via the actuation input port
(get_actuation_input_port()) and applied by the PD controllers is reported by
the net actuation port (get_net_actuation_output_port()). That is, the net
actuation port reports the total actuation applied by a given actuator.

@note PD controllers are ignored when a joint is locked (see Joint::Lock()), and
thus they have no effect on the actuation output.

@anchor sdf_loading
                 ### Loading models from SDFormat files

Drake has the capability to load multibody models from SDFormat and URDF
files.  Consider the example below which loads an acrobot model:
@code
  MultibodyPlant<T> acrobot;
  SceneGraph<T> scene_graph;
  Parser parser(&acrobot, &scene_graph);
  const std::string relative_name =
    "drake/multibody/benchmarks/acrobot/acrobot.sdf";
  const std::string full_name = FindResourceOrThrow(relative_name);
  parser.AddModels(full_name);
@endcode
As in the example above, for models including visual geometry, collision
geometry or both, the user must specify a SceneGraph for geometry handling.
You can find a full example of the LQR controlled acrobot in
examples/multibody/acrobot/run_lqr.cc.

AddModelFromFile() can be invoked multiple times on the same plant in order
to load multiple model instances.  Other methods are available on Parser
such as AddModels() which allows creating model instances per
each `<model>` tag found in the file. Please refer to each of these
methods' documentation for further details.

@anchor working_with_scenegraph
                  ### Working with %SceneGraph

@anchor add_multibody_plant_scene_graph
  #### Adding a %MultibodyPlant connected to a %SceneGraph to your %Diagram

Probably the simplest way to add and wire up a MultibodyPlant with
a SceneGraph in your Diagram is using AddMultibodyPlantSceneGraph().

Recommended usages:

Assign to a MultibodyPlant reference (ignoring the SceneGraph):
@code
  MultibodyPlant<double>& plant =
      AddMultibodyPlantSceneGraph(&builder, 0.0 /+ time_step +/);
  plant.DoFoo(...);
@endcode
This flavor is the simplest, when the SceneGraph is not explicitly needed.
(It can always be retrieved later via GetSubsystemByName("scene_graph").)

Assign to auto, and use the named public fields:
@code
  auto items = AddMultibodyPlantSceneGraph(&builder, 0.0 /+ time_step +/);
  items.plant.DoFoo(...);
  items.scene_graph.DoBar(...);
@endcode
or taking advantage of C++17's structured binding
@code
  auto [plant, scene_graph] = AddMultibodyPlantSceneGraph(&builder, 0.0);
  ...
  plant.DoFoo(...);
  scene_graph.DoBar(...);
@endcode
This is the easiest way to use both the plant and scene_graph.

Assign to already-declared pointer variables:
@code
  MultibodyPlant<double>* plant{};
  SceneGraph<double>* scene_graph{};
  std::tie(plant, scene_graph) =
      AddMultibodyPlantSceneGraph(&builder, 0.0 /+ time_step +/);
  plant->DoFoo(...);
  scene_graph->DoBar(...);
@endcode
This flavor is most useful when the pointers are class member fields
(and so perhaps cannot be references).

@anchor mbp_geometry_registration
              #### Registering geometry with a SceneGraph

%MultibodyPlant users can register geometry with a SceneGraph for
essentially two purposes; a) visualization and, b) contact modeling.

<!--TODO(SeanCurtis-TRI): update this comment as the number of SceneGraph
    roles changes. -->

Before any geometry registration takes place, a user **must** first make a
call to RegisterAsSourceForSceneGraph() in order to register the
%MultibodyPlant as a client of a SceneGraph instance, point at which the
plant will have assigned a valid geometry::SourceId.
At Finalize(), %MultibodyPlant will declare input/output ports as
appropriate to communicate with the SceneGraph instance on which
registrations took place. All geometry registration **must** be performed
pre-finalize.

%Multibodyplant declares an input port for geometric queries, see
get_geometry_query_input_port(). If %MultibodyPlant registers geometry with
a SceneGraph via calls to RegisterCollisionGeometry(), users may use this
port for geometric queries. The port must be connected to the same SceneGraph
used for registration. The preferred mechanism is to use
AddMultibodyPlantSceneGraph() as documented above.

In extraordinary circumstances, this can be done by hand and the setup process
will include:

1. Call to RegisterAsSourceForSceneGraph().
2. Calls to RegisterCollisionGeometry(), as many as needed.
3. Call to Finalize(), user is done specifying the model.
4. Connect geometry::SceneGraph::get_query_output_port() to
   get_geometry_query_input_port().
5. Connect get_geometry_poses_output_port() to
   geometry::SceneGraph::get_source_pose_port()

Refer to the documentation provided in each of the methods above for further
details.

@anchor accessing_contact_properties
              #### Accessing point contact parameters
%MultibodyPlant's point contact model looks for model parameters stored as
geometry::ProximityProperties by geometry::SceneGraph. These properties can
be obtained before or after context creation through
geometry::SceneGraphInspector APIs as outlined below. %MultibodyPlant expects
the following properties for point contact modeling:

|Group name|Property Name|Required|Property Type|Property Description|
|:--------:|:-----------:|:------:|:----------------:|:-------------------|
|material|coulomb_friction|yes¹|CoulombFriction<T>|Static and Dynamic friction.|
|material|point_contact_stiffness|no²|T| Penalty method stiffness.|
|material|hunt_crossley_dissipation |no²⁴|T| Penalty method dissipation.|
|material|relaxation_time|yes³⁴|T|Linear Kelvin–Voigt model parameter.|

¹ Collision geometry is required to be registered with a
  geometry::ProximityProperties object that contains the
  ("material", "coulomb_friction") property. If the property
  is missing, %MultibodyPlant will throw an exception.

² If the property is missing, %MultibodyPlant will use
  a heuristic value as the default. Refer to the
  section @ref mbp_penalty_method "Penalty method point contact" for further
  details.

³ When using a linear Kelvin–Voigt model of dissipation (for instance when
  selecting the SAP solver), collision geometry is required to be registered
  with a geometry::ProximityProperties object that contains the ("material",
  "relaxation_time") property. If the property is missing, an exception will be
  thrown.

⁴ We allow to specify both hunt_crossley_dissipation and relaxation_time for a
  given geometry. However only one of these will get used, depending on the
  configuration of the %MultibodyPlant. As an example, if the SAP solver is
  specified (see set_discrete_contact_solver()) only the relaxation_time is used
  while hunt_crossley_dissipation is ignored. Conversely, if the TAMSI solver is
  used (see set_discrete_contact_solver()) only hunt_crossley_dissipation is
  used while relaxation_time is ignored. Currently, a continuous %MultibodyPlant
  model will always use the Hunt & Crossley model and relaxation_time will be
  ignored.

Accessing and modifying contact properties requires interfacing with
geometry::SceneGraph's model inspector. Interfacing with a model inspector
obtained from geometry::SceneGraph will provide the default registered
values for a given parameter. These are the values that will
initially appear in a systems::Context created by CreateDefaultContext().
Subsequently, true system parameters can be accessed and changed through a
systems::Context once available. For both of the above cases, proximity
properties are accessed through geometry::SceneGraphInspector APIs.

Before context creation an inspector can be retrieved directly from SceneGraph
as:
@code
// For a SceneGraph<T> instance called scene_graph.
const geometry::SceneGraphInspector<T>& inspector =
    scene_graph.model_inspector();
@endcode
After context creation, an inspector can be retrieved from the state
stored in the context by the plant's geometry query input port:
@code
// For a MultibodyPlant<T> instance called mbp and a
// Context<T> called context.
const geometry::QueryObject<T>& query_object =
    mbp.get_geometry_query_input_port()
        .template Eval<geometry::QueryObject<T>>(context);
const geometry::SceneGraphInspector<T>& inspector =
    query_object.inspector();
@endcode
Once an inspector is available, proximity properties can be retrieved as:
@code
// For a body with GeometryId called geometry_id
const geometry::ProximityProperties* props =
    inspector.GetProximityProperties(geometry_id);
const CoulombFriction<T>& geometry_friction =
    props->GetProperty<CoulombFriction<T>>("material",
                                           "coulomb_friction");
@endcode

@anchor mbp_parameters
              ### Working with %MultibodyElement parameters
Several %MultibodyElements expose parameters, allowing the user flexible
modification of some aspects of the plant's model, post systems::Context
creation. For details, refer to the documentation for the MultibodyElement
whose parameters you are trying to modify/access (e.g. RigidBody,
FixedOffsetFrame, etc.)

As an example, here is how to access and modify rigid body mass parameters:
@code
  MultibodyPlant<double> plant;
  // ... Code to add bodies, finalize plant, and to obtain a context.
  const RigidBody<double>& body =
      plant.GetRigidBodyByName("BodyName");
  const SpatialInertia<double> M_BBo_B =
      body.GetSpatialInertiaInBodyFrame(context);
  // .. logic to determine a new SpatialInertia parameter for body.
  const SpatialInertia<double>& M_BBo_B_new = ....

  // Modify the body parameter for spatial inertia.
  body.SetSpatialInertiaInBodyFrame(&context, M_BBo_B_new);
@endcode

Another example, working with automatic differentiation in order to take
derivatives with respect to one of the bodies' masses:
@code
  MultibodyPlant<double> plant;
  // ... Code to add bodies, finalize plant, and to obtain a
  // context and a body's spatial inertia M_BBo_B.

  // Scalar convert the plant.
  unique_ptr<MultibodyPlant<AutoDiffXd>> plant_autodiff =
      systems::System<double>::ToAutoDiffXd(plant);
  unique_ptr<Context<AutoDiffXd>> context_autodiff =
      plant_autodiff->CreateDefaultContext();
  context_autodiff->SetTimeStateAndParametersFrom(context);

  const RigidBody<AutoDiffXd>& body =
      plant_autodiff->GetRigidBodyByName("BodyName");

  // Modify the body parameter for mass.
  const AutoDiffXd mass_autodiff(mass, Vector1d(1));
  body.SetMass(context_autodiff.get(), mass_autodiff);

  // M_autodiff(i, j).derivatives()(0), contains the derivatives of
  // M(i, j) with respect to the body's mass.
  MatrixX<AutoDiffXd> M_autodiff(plant_autodiff->num_velocities(),
      plant_autodiff->num_velocities());
  plant_autodiff->CalcMassMatrix(*context_autodiff, &M_autodiff);
@endcode

@anchor mbp_adding_elements
                   ### Adding modeling elements

<!-- TODO(amcastro-tri): Update this section to add force elements and
     constraints. -->

Add multibody elements to a %MultibodyPlant with methods like:

- Bodies: AddRigidBody()
- Joints: AddJoint()
- see @ref mbp_construction "Construction" for more.

All modeling elements **must** be added before Finalize() is called.
See @ref mbp_finalize_stage "Finalize stage" for a discussion.

@anchor mbp_modeling_contact
                          ### Modeling contact

Please refer to @ref drake_contacts "Contact Modeling in Drake" for details
on the available approximations, setup, and considerations for a multibody
simulation with frictional contact.

@anchor mbp_energy_and_power
                        ### Energy and Power
<!-- TODO(sherm1) Update this as issue #12942 gets resolved. -->
%MultibodyPlant implements the System energy and power methods, with
some limitations.
- Kinetic energy: fully implemented.
- Potential energy and conservative power: currently include only gravity
  and contributions from ForceElement objects; potential energy from
  compliant contact and joint limits are not included.
- Nonconservative power: currently includes only contributions from
  ForceElement objects; actuation and input port forces, joint damping,
  and dissipation from joint limits, friction, and contact dissipation
  are not included.

See Drake issue #12942 for more discussion.

@anchor mbp_finalize_stage
                           ### %Finalize() stage

Once the user is done adding modeling elements and registering geometry, a
call to Finalize() must be performed. This call will:
- Build the underlying tree structure of the multibody model,
- declare the plant's state,
- declare the plant's input and output ports,
- declare collision filters to ignore collisions among rigid bodies:
  - between rigid bodies connected by a joint,
  - within subgraphs of welded rigid bodies.
Note that MultibodyPlant will *not* introduce *any* collision filters
on deformable bodies.

<!-- TODO(amcastro-tri): Consider making the actual geometry registration
     with GS AFTER Finalize() so that we can tell if there are any bodies
     welded to the world to which we could just assign anchored geometry
     instead of dynamic geometry. This is an optimization and the API, and
     pre/post-finalize conditions should not change. -->

@anchor mbp_table_of_contents

@anchor mbp_references
                           ### References

- [Featherstone 2008] Featherstone, R., 2008.
    Rigid body dynamics algorithms. Springer.
- [Jain 2010] Jain, A., 2010.
    Robot and multibody dynamics: analysis and algorithms.
    Springer Science & Business Media.
- [Seth 2010] Seth, A., Sherman, M., Eastman, P. and Delp, S., 2010.
    Minimal formulation of joint motion for biomechanisms.
    Nonlinear dynamics, 62(1), pp.291-303.

@tparam_default_scalar
@ingroup systems */
template <typename T>
class MultibodyPlant : public internal::MultibodyTreeSystem<T> {
 public:
  DRAKE_NO_COPY_NO_MOVE_NO_ASSIGN(MultibodyPlant)

  /// @anchor mbp_input_and_output_ports
  /// @name                 Input and output ports
  /// These methods provide access to the Drake
  /// @ref systems::System "System" input and output ports
  /// as depicted in the MultibodyPlant class documentation.
  ///
  /// Actuation values can be provided through a single input port which
  /// describes the entire plant, or through multiple input ports which each
  /// provide the actuation values for a specific model instance. See
  /// AddJointActuator() and num_actuators().
  ///
  /// Output ports provide information about the entire %MultibodyPlant
  /// or its individual model instances.
  /// @{

  /// Returns the output port of all body poses in the world frame.
  /// You can obtain the pose `X_WB` of a body B in the world frame W with:
  /// @code
  ///   const auto& X_WB_all = plant.get_body_poses_output_port().
  ///       .Eval<std::vector<math::RigidTransform<double>>>(plant_context);
  ///   const BodyIndex arm_body_index = plant.GetBodyByName("arm").index();
  ///   const math::RigidTransform<double>& X_WArm = X_WB_all[arm_body_index];
  /// @endcode
  /// As shown in the example above, the resulting `std::vector` of body poses
  /// is indexed by BodyIndex, and it has size num_bodies().
  /// BodyIndex "zero" (0) always corresponds to the world body, with pose
  /// equal to the identity at all times.
  /// @throws std::exception if called pre-finalize.
  const systems::OutputPort<T>& get_body_poses_output_port() const;

  /// Returns the output port of all body spatial velocities in the world frame.
  /// You can obtain the spatial velocity `V_WB` of a body B in the world frame
  /// W with:
  /// @code
  ///   const auto& V_WB_all = plant.get_body_spatial_velocities_output_port().
  ///       .Eval<std::vector<SpatialVelocity<double>>>(plant_context);
  ///   const BodyIndex arm_body_index = plant.GetBodyByName("arm").index();
  ///   const SpatialVelocity<double>& V_WArm = V_WB_all[arm_body_index];
  /// @endcode
  /// As shown in the example above, the resulting `std::vector` of body spatial
  /// velocities is indexed by BodyIndex, and it has size num_bodies().
  /// BodyIndex "zero" (0) always corresponds to the world body, with zero
  /// spatial velocity at all times.
  /// @throws std::exception if called pre-finalize.
  const systems::OutputPort<T>& get_body_spatial_velocities_output_port() const;

  /// Returns the output port of all body spatial accelerations in the world
  /// frame. You can obtain the spatial acceleration `A_WB` of a body B in the
  /// world frame W with:
  /// @code
  ///   const auto& A_WB_all =
  ///   plant.get_body_spatial_accelerations_output_port().
  ///       .Eval<std::vector<SpatialAcceleration<double>>>(plant_context);
  ///   const BodyIndex arm_body_index = plant.GetBodyByName("arm").index();
  ///   const SpatialVelocity<double>& A_WArm = A_WB_all[arm_body_index];
  /// @endcode
  /// As shown in the example above, the resulting `std::vector` of body spatial
  /// accelerations is indexed by BodyIndex, and it has size num_bodies().
  /// BodyIndex "zero" (0) always corresponds to the world body, with zero
  /// spatial acceleration at all times.
  /// @throws std::exception if called pre-finalize.
  const systems::OutputPort<T>& get_body_spatial_accelerations_output_port()
      const;

  /// Returns a constant reference to the input port for external actuation for
  /// all actuated dofs. This input port is a vector valued port indexed by
  /// @ref JointActuatorIndex, see JointActuator::index(), and can be set with
  /// JointActuator::set_actuation_vector().
  /// Refer to @ref mbp_actuation "Actuation" for further details.
  /// @pre Finalize() was already called on `this` plant.
  /// @throws std::exception if called before Finalize().
  const systems::InputPort<T>& get_actuation_input_port() const;

  /// Returns a constant reference to the output port that reports actuation
  /// values applied through joint actuators. This output port is a vector
  /// valued port indexed by @ref JointActuatorIndex, see
  /// JointActuator::index(). Models that include PD controllers will include
  /// their contribution in this port, refer to @ref mbp_actuation "Actuation"
  /// for further details.
  /// @note PD controllers are not considered for actuators on locked joints,
  /// see Joint::Lock(). Therefore they do not contribute to this port.
  /// @pre Finalize() was already called on `this` plant.
  /// @throws std::exception if called before Finalize().
  const systems::OutputPort<T>& get_net_actuation_output_port() const;

  /// Returns a constant reference to the input port for external actuation for
  /// a specific model instance. This is a vector valued port with entries
  /// ordered by monotonically increasing @ref JointActuatorIndex within
  /// `model_instance`. Refer to @ref mbp_actuation "Actuation" for further
  /// details.
  ///
  /// Every model instance in `this` plant model has an actuation input port,
  /// even if zero sized (for model instance with no actuators).
  ///
  /// @see GetJointActuatorIndices(), GetActuatedJointIndices().
  ///
  /// @pre Finalize() was already called on `this` plant.
  /// @throws std::exception if called before Finalize().
  /// @throws std::exception if the model instance does not exist.
  const systems::InputPort<T>& get_actuation_input_port(
      ModelInstanceIndex model_instance) const;

  /// For models with PD controlled joint actuators, returns the port to provide
  /// the desired state for the full `model_instance`.
  /// Refer to @ref mbp_actuation "Actuation" for further details.
  ///
  /// For consistency with get_actuation_input_port(), each model instance in
  /// `this` plant model has a desired states input port, even if zero sized
  /// (for model instance with no actuators.)
  ///
  /// @note This is a vector valued port of size
  /// 2*num_actuators(model_instance), where we assumed 1-DOF actuated joints.
  /// This is true even for unactuated models, for which this port is zero
  /// sized. This port must provide one desired position and one desired
  /// velocity per joint actuator. Desired state is assumed to be packed as xd =
  /// [qd, vd] that is, configurations first followed by velocities.
  /// Configurations in qd are ordered by JointActuatorIndex, see
  /// JointActuator::set_actuation_vector(). Similarly for velocities in vd.
  ///
  /// @warning If a user specifies a PD controller for an actuator from a given
  /// model instance, then all actuators of that model instance are required to
  /// be PD controlled.
  ///
  /// @warning It is required to connect this port for PD controlled model
  /// instances.
  const systems::InputPort<T>& get_desired_state_input_port(
      ModelInstanceIndex model_instance) const;

  /// Returns a constant reference to the vector-valued input port for applied
  /// generalized forces, and the vector will be added directly into `tau` (see
  /// @ref mbp_equations_of_motion "System dynamics"). This vector is ordered
  /// using the same convention as the plant velocities: you can set the
  /// generalized forces that will be applied to model instance i using, e.g.,
  /// `SetVelocitiesInArray(i, model_forces, &force_array)`.
  /// @throws std::exception if called before Finalize().
  const systems::InputPort<T>& get_applied_generalized_force_input_port() const;

  /// Returns a constant reference to the input port for applying spatial
  /// forces to bodies in the plant. The data type for the port is an
  /// std::vector of ExternallyAppliedSpatialForce; any number of spatial forces
  /// can be applied to any number of bodies in the plant.
  const systems::InputPort<T>& get_applied_spatial_force_input_port() const;

  /// Returns a constant reference to the input port used to perform geometric
  /// queries on a SceneGraph. See SceneGraph::get_query_output_port().
  /// Refer to section @ref mbp_geometry "Geometry" of this class's
  /// documentation for further details on collision geometry registration and
  /// connection with a SceneGraph.
  const systems::InputPort<T>& get_geometry_query_input_port() const;

  /// Returns a constant reference to the output port for the multibody state
  /// x = [q, v] of the model.
  /// @pre Finalize() was already called on `this` plant.
  /// @throws std::exception if called before Finalize().
  const systems::OutputPort<T>& get_state_output_port() const;

  /// Returns a constant reference to the output port for the state
  /// xᵢ = [qᵢ vᵢ] of model instance i. (Here qᵢ ⊆ q and vᵢ ⊆ v.)
  /// @pre Finalize() was already called on `this` plant.
  /// @throws std::exception if called before Finalize().
  /// @throws std::exception if the model instance does not exist.
  const systems::OutputPort<T>& get_state_output_port(
      ModelInstanceIndex model_instance) const;

  /// Returns a constant reference to the output port for generalized
  /// accelerations v̇ of the model.
  /// @pre Finalize() was already called on `this` plant.
  /// @throws std::exception if called before Finalize().
  const systems::OutputPort<T>& get_generalized_acceleration_output_port()
      const;

  /// Returns a constant reference to the output port for the generalized
  /// accelerations v̇ᵢ ⊆ v̇ for model instance i.
  /// @pre Finalize() was already called on `this` plant.
  /// @throws std::exception if called before Finalize().
  /// @throws std::exception if the model instance does not exist.
  const systems::OutputPort<T>& get_generalized_acceleration_output_port(
      ModelInstanceIndex model_instance) const;

  /// Returns a constant reference to the output port of generalized contact
  /// forces for a specific model instance.
  ///
  /// @pre Finalize() was already called on `this` plant.
  /// @throws std::exception if called before Finalize().
  /// @throws std::exception if the model instance does not exist.
  const systems::OutputPort<T>& get_generalized_contact_forces_output_port(
      ModelInstanceIndex model_instance) const;

  /// Returns the port for joint reaction forces.
  /// A Joint models the kinematical relationship which characterizes the
  /// possible relative motion between two bodies. In Drake, a joint connects a
  /// frame `Jp` on _parent_ body P with a frame `Jc` on a _child_ body C. This
  /// usage of the terms _parent_ and _child_ is just a convention and implies
  /// nothing about the inboard-outboard relationship between the bodies. Since
  /// a Joint imposes a kinematical relationship which characterizes the
  /// possible relative motion between frames Jp and Jc, reaction forces on each
  /// body are established. That is, we could cut the model at the joint and
  /// replace it with equivalent forces equal to these reaction forces in order
  /// to attain the same motions of the mechanical system.
  ///
  /// This output port allows to evaluate the reaction force `F_CJc_Jc` on the
  /// _child_ body C, at `Jc`, and expressed in Jc for all joints in the model.
  /// This port evaluates to a vector of type std::vector<SpatialForce<T>> and
  /// size num_joints() indexed by JointIndex, see Joint::index(). Each entry
  /// corresponds to the spatial force `F_CJc_Jc` applied on the joint's child
  /// body C (Joint::child_body()), at the joint's child frame `Jc`
  /// (Joint::frame_on_child()) and expressed in frame `Jc`.
  ///
  /// @throws std::exception if called pre-finalize.
  const systems::OutputPort<T>& get_reaction_forces_output_port() const;

  /// Returns a constant reference to the port that outputs ContactResults.
  /// @throws std::exception if called pre-finalize, see Finalize().
  const systems::OutputPort<T>& get_contact_results_output_port() const;

  /// Returns the output port of frames' poses to communicate with a
  /// SceneGraph.
  const systems::OutputPort<T>& get_geometry_poses_output_port() const;
  /// @} <!-- Input and output ports -->

  /// @anchor mbp_construction
  /// @name                   Construction
  /// To add modeling elements like bodies, joints, force elements, constraints,
  /// etc. to a %MultibodyPlant, use one of the following construction methods.
  /// Once _all_ modeling elements have been added, the Finalize() method
  /// **must** be called. A call to any construction method **after** a call to
  /// Finalize() causes an exception to be thrown.
  ///  After calling Finalize(), you may invoke %MultibodyPlant
  /// methods that perform computations. See Finalize() for details.
  /// @{

  /// This constructor creates a plant with a single "world" body.
  /// Therefore, right after creation, num_bodies() returns one.
  ///
  /// %MultibodyPlant offers two different modalities to model mechanical
  /// systems in time. These are:
  ///  1. As a discrete system with periodic updates, `time_step` is strictly
  ///     greater than zero.
  ///  2. As a continuous system, `time_step` equals exactly zero.
  ///
  /// Currently the discrete model is preferred for simulation given its
  /// robustness and speed in problems with frictional contact. However this
  /// might change as we work towards developing better strategies to model
  /// contact.
  /// See @ref time_advancement_strategy
  /// "Choice of Time Advancement Strategy" for further details.
  ///
  /// @warning Users should be aware of current limitations in either modeling
  /// modality. While the discrete model is often the preferred option for
  /// problems with frictional contact given its robustness and speed, it might
  /// become unstable when using large feedback gains, high damping or large
  /// external forcing. %MultibodyPlant will throw an exception whenever the
  /// discrete solver is detected to fail.
  /// Conversely, the continuous modality has the potential to leverage the
  /// robustness and accuracy control provide by Drake's integrators. However
  /// thus far this has proved difficult in practice and especially due to poor
  /// performance.
  ///
  /// <!-- TODO(amcastro-tri): Update the @warning messages in these docs if the
  ///      best practices advice changes as our solvers evolve. -->
  ///
  /// @param[in] time_step
  ///   Indicates whether `this` plant is modeled as a continuous system
  ///   (`time_step = 0`) or as a discrete system with periodic updates of
  ///   period `time_step > 0`. See @ref time_advancement_strategy
  ///   "Choice of Time Advancement Strategy" for further details.
  ///
  /// @warning Currently the continuous modality with `time_step = 0` does not
  /// support joint limits for simulation, these are ignored. %MultibodyPlant
  /// prints a warning to console if joint limits are provided. If your
  /// simulation requires joint limits currently you must use a discrete
  /// %MultibodyPlant model.
  ///
  /// @throws std::exception if `time_step` is negative.
  explicit MultibodyPlant(double time_step);

  /// Scalar-converting copy constructor.  See @ref system_scalar_conversion.
  template <typename U>
  explicit MultibodyPlant(const MultibodyPlant<U>& other);

  /// Creates a rigid body with the provided name and spatial inertia.  This
  /// method returns a constant reference to the body just added, which will
  /// remain valid for the lifetime of `this` %MultibodyPlant.
  ///
  /// Example of usage:
  /// @code
  ///   MultibodyPlant<T> plant;
  ///   // ... Code to define spatial_inertia, a SpatialInertia<T> object ...
  ///   ModelInstanceIndex model_instance = plant.AddModelInstance("instance");
  ///   const RigidBody<T>& body =
  ///     plant.AddRigidBody("BodyName", model_instance, spatial_inertia);
  /// @endcode
  ///
  /// @param[in] name
  ///   A string that identifies the new body to be added to `this` model. A
  ///   std::runtime_error is thrown if a body named `name` already is part of
  ///   @p model_instance. See HasBodyNamed(), Body::name().
  /// @param[in] model_instance
  ///   A model instance index which this body is part of.
  /// @param[in] M_BBo_B
  ///   The SpatialInertia of the new rigid body to be added to `this`
  ///   %MultibodyPlant, computed about the body frame origin `Bo` and expressed
  ///   in the body frame B.
  /// @returns A constant reference to the new RigidBody just added, which will
  ///          remain valid for the lifetime of `this` %MultibodyPlant.
  const RigidBody<T>& AddRigidBody(const std::string& name,
                                   ModelInstanceIndex model_instance,
                                   const SpatialInertia<double>& M_BBo_B) {
    DRAKE_MBP_THROW_IF_FINALIZED();
    // Add the actual rigid body to the model.
    const RigidBody<T>& body =
        this->mutable_tree().AddRigidBody(name, model_instance, M_BBo_B);
    // Each entry of visual_geometries_, ordered by body index, contains a
    // std::vector of geometry ids for that body. The emplace_back() below
    // resizes visual_geometries_ to store the geometry ids for the body we
    // just added.
    // Similarly for the collision_geometries_ vector.
    DRAKE_DEMAND(visual_geometries_.size() == body.index());
    visual_geometries_.emplace_back();
    DRAKE_DEMAND(collision_geometries_.size() == body.index());
    collision_geometries_.emplace_back();
    RegisterRigidBodyWithSceneGraph(body);
    return body;
  }

  /// Creates a rigid body with the provided name and spatial inertia.  This
  /// method returns a constant reference to the body just added, which will
  /// remain valid for the lifetime of `this` %MultibodyPlant.  The body will
  /// use the default model instance
  /// (@ref model_instance "more on model instances").
  ///
  /// Example of usage:
  /// @code
  ///   MultibodyPlant<T> plant;
  ///   // ... Code to define spatial_inertia, a SpatialInertia<T> object ...
  ///   const RigidBody<T>& body =
  ///     plant.AddRigidBody("BodyName", spatial_inertia);
  /// @endcode
  ///
  /// @param[in] name
  ///   A string that identifies the new body to be added to `this` model. A
  ///   std::runtime_error is thrown if a body named `name` already is part of
  ///   the model in the default model instance. See HasBodyNamed(),
  ///   Body::name().
  /// @param[in] M_BBo_B
  ///   The SpatialInertia of the new rigid body to be added to `this`
  ///   %MultibodyPlant, computed about the body frame origin `Bo` and expressed
  ///   in the body frame B.
  /// @returns A constant reference to the new RigidBody just added, which will
  ///          remain valid for the lifetime of `this` %MultibodyPlant.
  /// @throws std::exception if additional model instances have been created
  ///                        beyond the world and default instances.
  const RigidBody<T>& AddRigidBody(const std::string& name,
                                   const SpatialInertia<double>& M_BBo_B) {
    if (num_model_instances() != 2) {
      throw std::logic_error(
          "This model has more model instances than the default.  Please "
          "call AddRigidBody with an explicit model instance.");
    }

    return AddRigidBody(name, default_model_instance(), M_BBo_B);
  }

  /// This method adds a Frame of type `FrameType<T>`. For more information,
  /// please see the corresponding constructor of `FrameType`.
  /// @tparam FrameType Template which will be instantiated on `T`.
  /// @param frame Unique pointer frame instance.
  /// @returns A constant reference to the new Frame just added, which will
  ///          remain valid for the lifetime of `this` %MultibodyPlant.
  template <template <typename> class FrameType>
  const FrameType<T>& AddFrame(std::unique_ptr<FrameType<T>> frame) {
    return this->mutable_tree().AddFrame(std::move(frame));
  }

  /// This method adds a Joint of type `JointType` between two bodies.
  /// For more information, see the below overload of `AddJoint<>`.
  template <template <typename Scalar> class JointType>
  const JointType<T>& AddJoint(std::unique_ptr<JointType<T>> joint) {
    static_assert(std::is_convertible_v<JointType<T>*, Joint<T>*>,
                  "JointType must be a sub-class of Joint<T>.");
    DRAKE_MBP_THROW_IF_FINALIZED();
    const JointType<T>& result =
        this->mutable_tree().AddJoint(std::move(joint));
    return result;
  }

  // clang-format off (to preserve link to image)
  /// This method adds a Joint of type `JointType` between two bodies.
  /// The two bodies connected by this Joint object are referred to as _parent_
  /// and _child_ bodies. The parent/child ordering defines the sign conventions
  /// for the generalized coordinates and the coordinate ordering for multi-DOF
  /// joints.
  ///
  /// <!-- NOLINTNEXTLINE(whitespace/line_length) -->
  /// @image html drake/multibody/plant/images/BodyParentChildJointCM.png
  /// width=50%
  ///
  /// Note: The previous figure also shows Pcm which is body P's center of mass
  /// and point Bcm which is body B's center of mass.
  ///
  /// As explained in the Joint class's documentation, in Drake we define a
  /// frame F attached to the parent body P with pose `X_PF` and a frame M
  /// attached to the child body B with pose `X_BM`. This method helps creating
  /// a joint between two bodies with fixed poses `X_PF` and `X_BM`.
  /// Refer to the Joint class's documentation for more details.
  ///
  /// @param name
  ///   A string that uniquely identifies the new joint to be added to `this`
  ///   model. A std::runtime_error is thrown if a joint named `name` already is
  ///   part of the model. See HasJointNamed(), Joint::name().
  /// @param[in] parent
  ///   The parent body connected by the new joint.
  /// @param[in] X_PF
  ///   The fixed pose of frame F attached to the parent body, measured in
  ///   the frame P of that body. `X_PF` is an optional parameter; empty curly
  ///   braces `{}` imply that frame F **is** the same body frame P. If instead
  ///   your intention is to make a frame F with pose `X_PF` equal to the
  ///   identity pose, provide `RigidTransform<double>::Identity()` as your
  ///   input. When non-nullopt, adds a FixedOffsetFrame named `{name}_parent`.
  /// @param[in] child
  ///   The child body connected by the new joint.
  /// @param[in] X_BM
  ///   The fixed pose of frame M attached to the child body, measured in
  ///   the frame B of that body. `X_BM` is an optional parameter; empty curly
  ///   braces `{}` imply that frame M **is** the same body frame B. If instead
  ///   your intention is to make a frame M with pose `X_BM` equal to the
  ///   identity pose, provide `RigidTransform<double>::Identity()` as your
  ///   input.  When non-nullopt, adds a FixedOffsetFrame named `{name}_child`.
  /// @param[in] args
  ///   Zero or more parameters provided to the constructor of the new joint. It
  ///   must be the case that
  ///   `JointType<T>(
  ///   const std::string&, const Frame<T>&, const Frame<T>&, args)` is a valid
  ///   constructor.
  /// @tparam JointType The type of the Joint to add.
  /// @returns A constant reference to the new joint just added, of type
  ///   `JointType<T>` specialized on the scalar type T of `this`
  ///   %MultibodyPlant. It will remain valid for the lifetime of `this`
  ///   %MultibodyPlant.
  ///
  /// Example of usage:
  /// @code
  ///   MultibodyPlant<T> plant;
  ///   // Code to define bodies serving as the joint's parent and child bodies.
  ///   const RigidBody<double>& body_1 =
  ///     plant.AddRigidBody("Body1", SpatialInertia<double>(...));
  ///   const RigidBody<double>& body_2 =
  ///     plant.AddRigidBody("Body2", SpatialInertia<double>(...));
  ///   // Body 1 serves as parent, Body 2 serves as child.
  ///   // Define the pose X_BM of a frame M rigidly attached to child body B.
  ///   const RevoluteJoint<double>& elbow =
  ///     plant.AddJoint<RevoluteJoint>(
  ///       "Elbow",                /* joint name */
  ///       body_1,                 /* parent body */
  ///       {},                     /* frame F IS the parent body frame P */
  ///       body_2,                 /* child body, the pendulum */
  ///       X_BM,                   /* pose of frame M in the body frame B */
  ///       Vector3d::UnitZ());     /* revolute axis in this case */
  /// @endcode
  ///
  /// @throws std::exception if `this` %MultibodyPlant already contains a joint
  ///     with the given `name`.  See HasJointNamed(), Joint::name().
  /// @throws std::exception if parent and child are the same body or if
  ///     they are not both from `this` %MultibodyPlant.
  ///
  /// @see The Joint class's documentation for further details on how a Joint
  /// is defined.
  template <template <typename> class JointType, typename... Args>
  const JointType<T>& AddJoint(
      const std::string& name, const Body<T>& parent,
      const std::optional<math::RigidTransform<double>>& X_PF,
      const Body<T>& child,
      const std::optional<math::RigidTransform<double>>& X_BM, Args&&... args) {
    // TODO(Mitiguy) Per discussion in PR# 13961 and issues #12789 and #13040,
    //  consider changing frame F to frame Jp and changing frame M to frame Jc.
    static_assert(std::is_base_of_v<Joint<T>, JointType<T>>,
                  "JointType<T> must be a sub-class of Joint<T>.");
    DRAKE_MBP_THROW_IF_FINALIZED();
    const JointType<T>& result =
        this->mutable_tree().template AddJoint<JointType>(
            name, parent, X_PF, child, X_BM, std::forward<Args>(args)...);
    return result;
  }
  // clang-format on

  /// Welds `frame_on_parent_F` and `frame_on_child_M` with relative pose
  /// `X_FM`. That is, the pose of frame M in frame F is fixed, with value
  /// `X_FM`.  If `X_FM` is omitted, the identity transform will be used. The
  /// call to this method creates and adds a new WeldJoint to the model.  The
  /// new WeldJoint is named as:
  ///     frame_on_parent_F.name() + "_welds_to_" + frame_on_child_M.name().
  /// @returns a constant reference to the WeldJoint welding frames
  /// F and M.
  /// @throws std::exception if the weld produces a duplicate joint name.
  const WeldJoint<T>& WeldFrames(const Frame<T>& frame_on_parent_F,
                                 const Frame<T>& frame_on_child_M,
                                 const math::RigidTransform<double>& X_FM =
                                     math::RigidTransform<double>::Identity());

  /// Adds a new force element model of type `ForceElementType` to `this`
  /// %MultibodyPlant.  The arguments to this method `args` are forwarded to
  /// `ForceElementType`'s constructor.
  /// @param[in] args
  ///   Zero or more parameters provided to the constructor of the new force
  ///   element. It must be the case that
  ///   `ForceElementType<T>(args)` is a valid constructor.
  /// @tparam ForceElementType The type of the ForceElement to add.  As there
  /// is always a UniformGravityFieldElement present (accessible through
  /// gravity_field()), an exception will be thrown if this function is called
  /// to add another UniformGravityFieldElement.
  /// @returns A constant reference to the new ForceElement just added, of type
  ///   `ForceElementType<T>` specialized on the scalar type T of `this`
  ///   %MultibodyPlant. It will remain valid for the lifetime of `this`
  ///   %MultibodyPlant.
  /// @see The ForceElement class's documentation for further details on how a
  /// force element is defined.
  template <template <typename Scalar> class ForceElementType, typename... Args>
  const ForceElementType<T>& AddForceElement(Args&&... args) {
    DRAKE_MBP_THROW_IF_FINALIZED();
    return this->mutable_tree().template AddForceElement<ForceElementType>(
        std::forward<Args>(args)...);
  }

  /// Creates and adds a JointActuator model for an actuator acting on a given
  /// `joint`.
  /// This method returns a constant reference to the actuator just added, which
  /// will remain valid for the lifetime of `this` plant.
  ///
  /// @param[in] name
  ///   A string that uniquely identifies the new actuator to be added to `this`
  ///   model. A std::runtime_error is thrown if an actuator with the same name
  ///   already exists in the model. See HasJointActuatorNamed().
  /// @param[in] joint
  ///   The Joint to be actuated by the new JointActuator.
  /// @param[in] effort_limit
  ///   The maximum effort for the actuator. It must be strictly positive,
  ///   otherwise an std::exception is thrown. If +∞, the actuator has no limit,
  ///   which is the default. The effort limit has physical units in accordance
  ///   to the joint type it actuates. For instance, it will have units of
  ///   N⋅m (torque) for revolute joints while it will have units of N (force)
  ///   for prismatic joints.
  /// @note The effort limit is unused by MultibodyPlant and is simply provided
  /// here for bookkeeping purposes. It will not, for instance, saturate
  /// external actuation inputs based on this value. If, for example, a user
  /// intends to saturate the force/torque that is applied to the MultibodyPlant
  /// via this actuator, the user-level code (e.g., a controller) should query
  /// this effort limit and impose the saturation there.
  /// @returns A constant reference to the new JointActuator just added, which
  /// will remain valid for the lifetime of `this` plant.
  /// @throws std::exception if `joint.num_velocities() > 1` since for now we
  /// only support actuators for single dof joints.
  const JointActuator<T>& AddJointActuator(
      const std::string& name, const Joint<T>& joint,
      double effort_limit = std::numeric_limits<double>::infinity());

  /// Creates a new model instance.  Returns the index for the model
  /// instance.
  ///
  /// @param[in] name
  ///   A string that uniquely identifies the new instance to be added to `this`
  ///   model. An exception is thrown if an instance with the same name
  ///   already exists in the model. See HasModelInstanceNamed().
  ModelInstanceIndex AddModelInstance(const std::string& name) {
    return this->mutable_tree().AddModelInstance(name);
  }

  /// Renames an existing model instance.
  ///
  /// @param[in] model_instance
  ///   The instance to rename.
  /// @param[in] name
  ///   A string that uniquely identifies the instance within `this` model.
  /// @throws std::exception if called after Finalize().
  /// @throws std::exception if `model_instance` is not a valid index.
  /// @throws std::exception if HasModelInstanceNamed(`name`) is true.
  void RenameModelInstance(ModelInstanceIndex model_instance,
                           const std::string& name);

  /// This method must be called after all elements in the model (joints,
  /// bodies, force elements, constraints, etc.) are added and before any
  /// computations are performed.
  /// It essentially compiles all the necessary "topological information", i.e.
  /// how bodies, joints and, any other elements connect with each other, and
  /// performs all the required pre-processing to enable computations at a
  /// later stage.
  ///
  /// If the finalize stage is successful, the topology of this %MultibodyPlant
  /// is valid, meaning that the topology is up-to-date after this call.
  /// No more multibody elements can be added after a call to Finalize().
  ///
  /// At Finalize(), state and input/output ports for `this` plant are declared.
  ///
  /// For a full account of the effects of Finalize(), see
  /// @ref mbp_finalize_stage "Finalize() stage".
  ///
  /// @see is_finalized(), @ref mbp_finalize_stage "Finalize() stage".
  ///
  /// @throws std::exception if the %MultibodyPlant has already been
  /// finalized.
  void Finalize();
  /// @}

  /// @anchor mbp_constraints
  /// @name                      Constraints
  ///
  /// Set of APIs to define constraints. To mention a few important examples,
  /// constraints can be used to couple the motion of joints, to create
  /// kinematic loops, or to weld bodies together.
  ///
  /// Currently constraints are only supported for discrete %MultibodyPlant
  /// models and not for all discrete solvers, see
  /// set_discrete_contact_solver(). If the model contains constraints not
  /// supported by the discrete solver, the plant will throw an exception at
  /// Finalize() time. At this point the user has the option to either change
  /// the contact solver with set_discrete_contact_solver() or in the
  /// MultibodyPlantConfig, or to re-define the model so that such a constraint
  /// is not needed.
  ///
  /// Each constraint is identified with a MultibodyConstraintId returned
  /// by the function used to add it (e.g. AddCouplerConstraint()). It is
  /// possible to recover constraint specification parameters for each
  /// constraint with various introspection functions (e.g.
  /// get_coupler_constraint_specs()). Each constraint has an "active" status
  /// that is set to true by default. Query a constraint's active status with
  /// GetConstraintActiveStatus() and set its active status with
  /// SetConstraintActiveStatus().
  ///
  /// <!-- TODO(joemasterjohn): As different constraint types are added in a
  /// piecemeal fashion, the burden of managing and maintaining these different
  /// constraints becomes cumbersome for the plant. Consider a new
  /// MultibodyConstraintManager class to consolidate constraint management. -->
  /// @{

  /// Returns the total number of constraints specified by the user.
  int num_constraints() const {
    return num_coupler_constraints() + num_distance_constraints() +
           num_ball_constraints() + num_weld_constraints();
  }

  /// Returns the total number of coupler constraints specified by the user.
  int num_coupler_constraints() const {
    return ssize(coupler_constraints_specs_);
  }

  /// Returns the total number of distance constraints specified by the user.
  int num_distance_constraints() const {
    return ssize(distance_constraints_specs_);
  }

  /// Returns the total number of ball constraints specified by the user.
  int num_ball_constraints() const { return ssize(ball_constraints_specs_); }

  /// Returns the total number of weld constraints specified by the user.
  int num_weld_constraints() const { return ssize(weld_constraints_specs_); }

  /// (Internal use only) Returns the coupler constraint specification
  /// corresponding to `id`
  /// @throws if `id` is not a valid identifier for a coupler constraint.
  const internal::CouplerConstraintSpec& get_coupler_constraint_specs(
      MultibodyConstraintId id) const {
    DRAKE_THROW_UNLESS(coupler_constraints_specs_.count(id) > 0);
    return coupler_constraints_specs_.at(id);
  }

  /// (Internal use only) Returns the distance constraint specification
  /// corresponding to `id`
  /// @throws if `id` is not a valid identifier for a distance constraint.
  const internal::DistanceConstraintSpec& get_distance_constraint_specs(
      MultibodyConstraintId id) const {
    DRAKE_THROW_UNLESS(distance_constraints_specs_.count(id) > 0);
    return distance_constraints_specs_.at(id);
  }

  /// (Internal use only)  Returns the ball constraint specification
  /// corresponding to `id`
  /// @throws if `id` is not a valid identifier for a ball constraint.
  const internal::BallConstraintSpec& get_ball_constraint_specs(
      MultibodyConstraintId id) const {
    DRAKE_THROW_UNLESS(ball_constraints_specs_.count(id) > 0);
    return ball_constraints_specs_.at(id);
  }

  /// (Internal use only)  Returns the weld constraint specification
  /// corresponding to `id`
  /// @throws if `id` is not a valid identifier for a weld constraint.
  const internal::WeldConstraintSpec& get_weld_constraint_specs(
      MultibodyConstraintId id) const {
    DRAKE_THROW_UNLESS(weld_constraints_specs_.count(id) > 0);
    return weld_constraints_specs_.at(id);
  }

  /// (Internal use only)  Returns a reference to the all of the coupler
  /// constraints in this plant as a map from MultibodyConstraintId to
  /// CouplerConstraintSpec.
  const std::map<MultibodyConstraintId, internal::CouplerConstraintSpec>&
  get_coupler_constraint_specs() const {
    return coupler_constraints_specs_;
  }

  /// (Internal use only) Returns a reference to the all of the distance
  /// constraints in this plant as a map from MultibodyConstraintId to
  /// DistanceConstraintSpec.
  const std::map<MultibodyConstraintId, internal::DistanceConstraintSpec>&
  get_distance_constraint_specs() const {
    return distance_constraints_specs_;
  }

  /// (Internal use only) Returns a reference to all of the ball constraints in
  /// this plant as a map from MultibodyConstraintId to BallConstraintSpec.
  const std::map<MultibodyConstraintId, internal::BallConstraintSpec>&
  get_ball_constraint_specs() const {
    return ball_constraints_specs_;
  }

  /// (Internal use only) Returns a reference to the all of the weld constraints
  /// in this plant as a map from MultibodyConstraintId to WeldConstraintSpec.
  const std::map<MultibodyConstraintId, internal::WeldConstraintSpec>&
  get_weld_constraint_specs() const {
    return weld_constraints_specs_;
  }

  /// Returns the active status of the constraint given by `id` in `context`.
  /// @throws std::exception if the %MultibodyPlant has not been finalized.
  /// @throws std::exception if `id` does not belong to any multibody constraint
  /// in `context`.
  bool GetConstraintActiveStatus(const systems::Context<T>& context,
                                 MultibodyConstraintId id) const;

  /// Sets the active status of the constraint given by `id` in `context`.
  /// @throws std::exception if the %MultibodyPlant has not been finalized.
  /// @throws std::exception if `context` == nullptr
  /// @throws std::exception if `id` does not belong to any multibody constraint
  /// in `context`.
  void SetConstraintActiveStatus(systems::Context<T>* context,
                                 MultibodyConstraintId id, bool status) const;

  /// Defines a holonomic constraint between two single-dof joints `joint0`
  /// and `joint1` with positions q₀ and q₁, respectively, such that q₀ = ρ⋅q₁ +
  /// Δq, where ρ is the gear ratio and Δq is a fixed offset. The gear ratio
  /// can have units if the units of q₀ and q₁ are different. For instance,
  /// between a prismatic and a revolute joint the gear ratio will specify the
  /// "pitch" of the resulting mechanism. As defined, `offset` has units of
  /// `q₀`.
  ///
  /// @note joint0 and/or joint1 can still be actuated, regardless of whether we
  /// have coupler constraint among them. That is, one or both of these joints
  /// can have external actuation applied to them.
  ///
  /// @note Generally, to couple (q0, q1, q2), the user would define a coupler
  /// between (q0, q1) and a second coupler between (q1, q2), or any
  /// combination therein.
  ///
  /// @throws if joint0 and joint1 are not both single-dof joints.
  /// @throws std::exception if the %MultibodyPlant has already been finalized.
  /// @throws std::exception if `this` %MultibodyPlant is not a discrete model
  /// (is_discrete() == false)
  /// @throws std::exception if `this` %MultibodyPlant's underlying contact
  /// solver is not SAP. (i.e. get_discrete_contact_solver() !=
  /// DiscreteContactSolver::kSap)
  MultibodyConstraintId AddCouplerConstraint(const Joint<T>& joint0,
                                             const Joint<T>& joint1,
                                             double gear_ratio,
                                             double offset = 0.0);

  /// Defines a distance constraint between a point P on a body A and a point Q
  /// on a body B.
  ///
  /// This constraint can be compliant, modeling a spring with free length
  /// `distance` and given `stiffness` and `damping` parameters between points P
  /// and Q. For d = ‖p_PQ‖, then a compliant distance constraint models a
  /// spring with force along p_PQ given by:
  ///
  ///    f = −stiffness ⋅ d − damping ⋅ ḋ
  ///
  /// @param[in] body_A Body to which point P is rigidly attached.
  /// @param[in] p_AP Position of point P in body A's frame.
  /// @param[in] body_B Body to which point Q is rigidly attached.
  /// @param[in] p_BQ Position of point Q in body B's frame.
  /// @param[in] distance Fixed length of the distance constraint, in meters. It
  /// must be strictly positive.
  /// @param[in] stiffness For modeling a spring with free length equal to
  /// `distance`, the stiffness parameter in N/m. Optional, with its default
  /// value being infinite to model a rigid massless rod of length `distance`
  /// connecting points A and B.
  /// @param[in] damping For modeling a spring with free length equal to
  /// `distance`, damping parameter in N⋅s/m. Optional, with its default value
  /// being zero for a non-dissipative constraint.
  /// @returns the id of the newly added constraint.
  ///
  /// @warning Currently, it is the user's responsibility to initialize the
  /// model's context in a configuration compatible with the newly added
  /// constraint.
  ///
  /// @warning A distance constraint is the wrong modeling choice if the
  /// distance needs to go through zero. To constrain two points to be
  /// coincident we need a 3-dof ball constraint, the 1-dof distance constraint
  /// is singular in this case. Therefore we require the distance parameter to
  /// be strictly positive.
  ///
  /// @throws std::exception if bodies A and B are the same body.
  /// @throws std::exception if `distance` is not strictly positive.
  /// @throws std::exception if `stiffness` is not positive or zero.
  /// @throws std::exception if `damping` is not positive or zero.
  /// @throws std::exception if the %MultibodyPlant has already been finalized.
  /// @throws std::exception if `this` %MultibodyPlant is not a discrete model
  /// (is_discrete() == false)
  /// @throws std::exception if `this` %MultibodyPlant's underlying contact
  /// solver is not SAP. (i.e. get_discrete_contact_solver() !=
  /// DiscreteContactSolver::kSap)
  MultibodyConstraintId AddDistanceConstraint(
      const Body<T>& body_A, const Vector3<double>& p_AP, const Body<T>& body_B,
      const Vector3<double>& p_BQ, double distance,
      double stiffness = std::numeric_limits<double>::infinity(),
      double damping = 0.0);

  /// Defines a constraint such that point P affixed to body A is coincident at
  /// all times with point Q affixed to body B, effectively modeling a
  /// ball-and-socket joint.
  ///
  /// @param[in] body_A Body to which point P is rigidly attached.
  /// @param[in] p_AP Position of point P in body A's frame.
  /// @param[in] body_B Body to which point Q is rigidly attached.
  /// @param[in] p_BQ Position of point Q in body B's frame.
  /// @returns the id of the newly added constraint.
  ///
  /// @throws std::exception if bodies A and B are the same body.
  /// @throws std::exception if the %MultibodyPlant has already been finalized.
  /// @throws std::exception if `this` %MultibodyPlant is not a discrete model
  /// (is_discrete() == false)
  /// @throws std::exception if `this` %MultibodyPlant's underlying contact
  /// solver is not SAP. (i.e. get_discrete_contact_solver() !=
  /// DiscreteContactSolver::kSap)
  MultibodyConstraintId AddBallConstraint(const Body<T>& body_A,
                                          const Vector3<double>& p_AP,
                                          const Body<T>& body_B,
                                          const Vector3<double>& p_BQ);

  /// Defines a constraint such that frame P affixed to body A is coincident at
  /// all times with frame Q affixed to body B, effectively modeling a weld
  /// joint.
  ///
  /// @param[in] body_A Body to which frame P is rigidly attached.
  /// @param[in] X_AP Pose of frame P in body A's frame.
  /// @param[in] body_B Body to which frame Q is rigidly attached.
  /// @param[in] X_BQ Pose of frame Q in body B's frame.
  /// @returns the id of the newly added constraint.
  ///
  /// @throws std::exception if bodies A and B are the same body.
  /// @throws std::exception if the %MultibodyPlant has already been finalized.
  /// @throws std::exception if `this` %MultibodyPlant is not a discrete model
  /// (is_discrete() == false)
  /// @throws std::exception if `this` %MultibodyPlant's underlying contact
  /// solver is not SAP. (i.e. get_discrete_contact_solver() !=
  /// DiscreteContactSolver::kSap)
  MultibodyConstraintId AddWeldConstraint(
      const Body<T>& body_A, const math::RigidTransform<double>& X_AP,
      const Body<T>& body_B, const math::RigidTransform<double>& X_BQ);

  /// <!-- TODO(#18732): Add getters to interrogate existing constraints.
  /// -->

  /// @}

  /// @anchor mbp_geometry
  /// @name                      Geometry
  ///
  /// The following geometry methods provide a convenient means for associating
  /// geometries with bodies. Ultimately, the geometries are owned by
  /// @ref geometry::SceneGraph "SceneGraph". These methods do the work of
  /// registering the requested geometries with SceneGraph and maintaining a
  /// mapping between the body and the registered data. Particularly, SceneGraph
  /// knows nothing about the concepts inherent in the %MultibodyPlant. These
  /// methods account for those differences as documented below.
  ///
  /// <h4>Geometry registration with roles</h4>
  ///
  /// Geometries can be associated with bodies via the `RegisterFooGeometry`
  /// family of methods. In SceneGraph, geometries have @ref geometry_roles
  /// "roles". The `RegisterCollisionGeometry()` methods register geometry with
  /// SceneGraph and assign it the proximity role. The
  /// `RegisterVisualGeometry()` methods do the same, but assign the
  /// illustration role.
  ///
  /// All geometry registration methods return a @ref geometry::GeometryId
  /// GeometryId. This is how SceneGraph refers to the geometries. The
  /// properties of an individual geometry can be accessed with its id and
  /// geometry::SceneGraphInspector and geometry::QueryObject (for its
  /// state-dependent pose in world).
  ///
  /// <h4>%Body frames and SceneGraph frames</h4>
  ///
  /// The first time a geometry registration method is called on a particular
  /// body, that body's frame B is registered with SceneGraph. As SceneGraph
  /// knows nothing about bodies, in the SceneGraph domain, the frame is simply
  /// notated as F; this is merely an alias for the body frame. Thus, the pose
  /// of the geometry G in the SceneGraph frame F is the same as the pose of the
  /// geometry in the body frame B; `X_FG = X_BG`.
  ///
  /// The model instance index of the body is passed to the SceneGraph frame as
  /// its "frame group". This can be retrieved from the
  /// geometry::SceneGraphInspector::GetFrameGroup(FrameId) method.
  ///
  /// Given a GeometryId, SceneGraph cannot report what _body_ it is affixed to.
  /// It can only report the SceneGraph alias frame F. But the following idiom
  /// can report the body:
  ///
  /// ```
  /// const MultibodyPlant<T>& plant = ...;
  /// const SceneGraphInspector<T>& inspector =  ...;
  /// const GeometryId g_id = id_from_some_query;
  /// const FrameId f_id = inspector.GetFrameId(g_id);
  /// const Body<T>* body = plant.GetBodyFromFrameId(f_id);
  /// ```
  /// See documentation of geometry::SceneGraphInspector on where to get an
  /// inspector.
  ///
  /// In %MultibodyPlant, frame names only have to be unique in a single
  /// model instance. However, SceneGraph knows nothing of model instances. So,
  /// to generate unique names for the corresponding frames in SceneGraph,
  /// when %MultibodyPlant registers the corresponding SceneGraph frame, it is
  /// named with a "scoped name". This is a concatenation of
  /// `[model instance name]::[body name]`. Searching for a frame with just the
  /// name `body name` will fail. (See Body::name() and GetModelInstanceName()
  /// for those values.)
  /// @{

  /// Registers `this` plant to serve as a source for an instance of
  /// SceneGraph. This registration allows %MultibodyPlant to
  /// register geometry with `scene_graph` for visualization and/or
  /// collision queries.  The string returned by `this->get_name()` is passed
  /// to SceneGraph's RegisterSource, so it is highly recommended that you give
  /// the plant a recognizable name before calling this.
  /// Successive registration calls with SceneGraph **must** be performed on
  /// the same instance to which the pointer argument `scene_graph` points
  /// to. Failure to do so will result in runtime exceptions.
  /// @param scene_graph
  ///   A valid non nullptr to the SceneGraph instance for which
  ///   `this` plant will sever as a source, see SceneGraph documentation
  ///   for further details.
  /// @returns the SourceId of `this` plant in `scene_graph`. It can also
  /// later on be retrieved with get_source_id().
  /// @throws std::exception if called post-finalize.
  /// @throws std::exception if `scene_graph` is the nullptr.
  /// @throws std::exception if called more than once.
  geometry::SourceId RegisterAsSourceForSceneGraph(
      geometry::SceneGraph<T>* scene_graph);

  /// Registers geometry in a SceneGraph with a given geometry::Shape to be
  /// used for visualization of a given `body`.
  ///
  /// @note Currently, the visual geometry will _also_ be assigned a perception
  /// role. Its render label's value will be equal to the body's index and its
  /// perception color will be the same as its illustration color (defaulting to
  /// gray if no color is provided). This behavior will change in the near
  /// future and code that directly relies on this behavior will break.
  ///
  /// @param[in] body
  ///   The body for which geometry is being registered.
  /// @param[in] X_BG
  ///   The fixed pose of the geometry frame G in the body frame B.
  /// @param[in] shape
  ///   The geometry::Shape used for visualization. E.g.: geometry::Sphere,
  ///   geometry::Cylinder, etc.
  /// @param[in] name
  ///   The name for the geometry. It must satisfy the requirements defined in
  ///   drake::geometry::GeometryInstance.
  /// @param[in] properties
  ///   The illustration properties for this geometry.
  /// @throws std::exception if called post-finalize.
  /// @throws std::exception if `scene_graph` does not correspond to the same
  /// instance with which RegisterAsSourceForSceneGraph() was called.
  /// @returns the id for the registered geometry.
  geometry::GeometryId RegisterVisualGeometry(
      const Body<T>& body, const math::RigidTransform<double>& X_BG,
      const geometry::Shape& shape, const std::string& name,
      const geometry::IllustrationProperties& properties);

  /// Overload for visual geometry registration; it converts the `diffuse_color`
  /// (RGBA with values in the range [0, 1]) into a
  /// geometry::DrakeVisualizer-compatible set of
  /// geometry::IllustrationProperties.
  geometry::GeometryId RegisterVisualGeometry(
      const Body<T>& body, const math::RigidTransform<double>& X_BG,
      const geometry::Shape& shape, const std::string& name,
      const Vector4<double>& diffuse_color);

  /// Overload for visual geometry registration; it relies on the downstream
  /// geometry::IllustrationProperties _consumer_ to provide default parameter
  /// values (see @ref geometry_roles for details).
  geometry::GeometryId RegisterVisualGeometry(
      const Body<T>& body, const math::RigidTransform<double>& X_BG,
      const geometry::Shape& shape, const std::string& name);

  /// Returns an array of GeometryId's identifying the different visual
  /// geometries for `body` previously registered with a SceneGraph.
  /// @note This method can be called at any time during the lifetime of `this`
  /// plant, either pre- or post-finalize, see Finalize().
  /// Post-finalize calls will always return the same value.
  /// @see RegisterVisualGeometry(), Finalize()
  const std::vector<geometry::GeometryId>& GetVisualGeometriesForBody(
      const Body<T>& body) const;

  /// Registers geometry in a SceneGraph with a given geometry::Shape to be
  /// used for the contact modeling of a given `body`.
  /// More than one geometry can be registered with a body, in which case the
  /// body's contact geometry is the union of all geometries registered to that
  /// body.
  ///
  /// @param[in] body
  ///   The body for which geometry is being registered.
  /// @param[in] X_BG
  ///   The fixed pose of the geometry frame G in the body frame B.
  /// @param[in] shape
  ///   The geometry::Shape used for visualization. E.g.: geometry::Sphere,
  ///   geometry::Cylinder, etc.
  /// @param[in] properties
  ///   The proximity properties associated with the collision geometry. They
  ///   *must* include the (`material`, `coulomb_friction`) property of type
  ///   CoulombFriction<double>.
  /// @throws std::exception if called post-finalize or if the properties are
  /// missing the coulomb friction property (or if it is of the wrong type).
  geometry::GeometryId RegisterCollisionGeometry(
      const Body<T>& body, const math::RigidTransform<double>& X_BG,
      const geometry::Shape& shape, const std::string& name,
      geometry::ProximityProperties properties);

  // TODO(SeanCurtis-TRI): Deprecate this in favor of simply passing properties.
  /// Overload which specifies a single property: coulomb_friction.
  geometry::GeometryId RegisterCollisionGeometry(
      const Body<T>& body, const math::RigidTransform<double>& X_BG,
      const geometry::Shape& shape, const std::string& name,
      const CoulombFriction<double>& coulomb_friction);

  /// Returns an array of GeometryId's identifying the different contact
  /// geometries for `body` previously registered with a SceneGraph.
  /// @note This method can be called at any time during the lifetime of `this`
  /// plant, either pre- or post-finalize, see Finalize().
  /// Post-finalize calls will always return the same value.
  /// @see RegisterCollisionGeometry(), Finalize()
  const std::vector<geometry::GeometryId>& GetCollisionGeometriesForBody(
      const Body<T>& body) const;

  /// Excludes the rigid collision geometries between two given collision filter
  /// groups. Note that collisions involving deformable geometries are not
  /// filtered by this function.
  /// @pre RegisterAsSourceForSceneGraph() has been called.
  /// @pre Finalize() has *not* been called.
  void ExcludeCollisionGeometriesWithCollisionFilterGroupPair(
      const std::pair<std::string, geometry::GeometrySet>&
          collision_filter_group_a,
      const std::pair<std::string, geometry::GeometrySet>&
          collision_filter_group_b);

  /// For each of the provided `bodies`, collects up all geometries that have
  /// been registered to that body. Intended to be used in conjunction with
  /// CollisionFilterDeclaration and
  /// CollisionFilterManager::Apply() to filter collisions between the
  /// geometries registered to the bodies.
  ///
  /// For example:
  /// ```
  /// // Don't report on collisions between geometries affixed to `body1`,
  /// // `body2`, or `body3`.
  /// std::vector<const RigidBody<T>*> bodies{&body1, &body2, &body3};
  /// geometry::GeometrySet set = plant.CollectRegisteredGeometries(bodies);
  /// scene_graph.collision_filter_manager().Apply(
  ///     CollisionFilterDeclaration().ExcludeWithin(set));
  /// ```
  ///
  /// @note There is a *very* specific order of operations:
  ///
  /// 1. Bodies and geometries must be added to the %MultibodyPlant.
  /// 2. Create GeometrySet instances from bodies (via this method).
  /// 3. Invoke SceneGraph::ExcludeCollisions*() to filter collisions.
  /// 4. Allocate context.
  ///
  /// Changing the order will cause exceptions to be thrown.
  ///
  /// @throws std::exception if `this` %MultibodyPlant was not
  /// registered with a SceneGraph.
  geometry::GeometrySet CollectRegisteredGeometries(
      const std::vector<const Body<T>*>& bodies) const;

  /// Given a geometry frame identifier, returns a pointer to the body
  /// associated with that id (nullptr if there is no such body).
  const Body<T>* GetBodyFromFrameId(geometry::FrameId frame_id) const {
    const auto it = frame_id_to_body_index_.find(frame_id);
    if (it == frame_id_to_body_index_.end()) return nullptr;
    return &internal_tree().get_body(it->second);
  }

  /// If the body with `body_index` belongs to the called plant, it returns
  /// the geometry::FrameId associated with it. Otherwise, it returns nullopt.
  std::optional<geometry::FrameId> GetBodyFrameIdIfExists(
      BodyIndex body_index) const {
    const auto it = body_index_to_frame_id_.find(body_index);
    if (it == body_index_to_frame_id_.end()) {
      return {};
    }
    return it->second;
  }

  /// If the body with `body_index` belongs to the called plant, it returns
  /// the geometry::FrameId associated with it. Otherwise this method throws
  /// an exception.
  /// @throws std::exception if the called plant does not have the body
  /// indicated by `body_index`.
  geometry::FrameId GetBodyFrameIdOrThrow(BodyIndex body_index) const {
    const auto it = body_index_to_frame_id_.find(body_index);
    if (it == body_index_to_frame_id_.end()) {
      throw std::logic_error("Body '" +
                             internal_tree().get_body(body_index).name() +
                             "' does not have geometry registered with it.");
    }
    return it->second;
  }
  /// @} <!-- Geometry -->

  /// @anchor mbp_contact_modeling
  /// @name                    Contact modeling
  /// Use methods in this section to choose the contact model and to provide
  /// parameters for that model. Currently Drake supports an advanced compliant
  /// contact model we call _Hydroelastic contact_ and a penalty-based point
  /// contact model as a reliable fallback.
  ///
  /// @anchor mbp_hydroelastic_materials_properties
  ///                      #### Hydroelastic contact
  ///
  /// To understand how material properties enter into the modeling of contact
  /// traction in the hydroelastic model, the user is referred to [R. Elandt
  /// 2019] for details.
  /// For brevity, here we limit ourselves to state the relationship between the
  /// material properties and the computation of the normal traction or
  /// "pressure" `p(x)` at each point `x` in the contact patch.
  /// Given two bodies A and B, with hydroelastic moduli `Eᵃ` and `Eᵇ`
  /// respectively and dissipation `dᵃ` and `dᵇ` respectively, we define the
  /// effective material properties of the pair according to: <pre>
  ///   E = Eᵃ⋅Eᵇ/(Eᵃ + Eᵇ),
  ///   d = E/Eᵃ⋅dᵃ + E/Eᵇ⋅dᵇ = Eᵇ/(Eᵃ+Eᵇ)⋅dᵃ + Eᵃ/(Eᵃ+Eᵇ)⋅dᵇ
  /// </pre>
  /// The effective hydroelastic modulus computation is based on that of the
  /// effective elastic modulus in the Hertz theory of contact.
  /// Dissipation is weighted in accordance with the
  /// fact that the softer material will deform more and faster and thus the
  /// softer material dissipation is given more importance. Hydroelastic
  /// modulus has units of pressure, i.e. `Pa (N/m²)`. The hydroelastic modulus
  /// is often estimated based on the Young's modulus of the material though in
  /// the hydroelastic model it represents an effective elastic property. For
  /// instance, [R. Elandt 2019] chooses to use `E = G`, with `G` the P-wave
  /// elastic modulus `G = (1-ν)/(1+ν)/(1-2ν)E`, with ν the Poisson
  /// ratio, consistent with the theory of layered solids in which plane
  /// sections remain planar after compression. Another possibility is to
  /// specify `E = E*`, with `E*` the effective elastic modulus given by the
  /// Hertz theory of contact, `E* = E/(1-ν²)`. In all of these cases a sound
  /// estimation of `hydroelastic_modulus` starts with the Young's modulus of
  /// the material.
  ///
  /// @note `hydroelastic_modulus` has units of stress/strain, measured in
  /// Pascal or N/m² like the more-familiar elastic moduli discussed above.
  /// However, it is quantitatively different and may require experimentation
  /// to match empirical behavior.
  ///
  /// We use a Hunt & Crossley dissipation model parameterized by a dissipation
  /// constant with units of inverse of velocity, i.e. `s/m`. See
  /// @ref mbp_dissipation_model "Modeling Dissipation" for more detail.
  ///
  /// The dissipation can be specified in one of two ways:
  ///
  /// - define it in an instance of geometry::ProximityProperties using
  ///   the function geometry::AddContactMaterial(), or
  /// - define it in an input URDF/SDFormat file as detailed here:
  ///   @ref tag_drake_hunt_crossley_dissipation.
  ///
  /// The hydroelastic modulus can be specified in one of two ways:
  ///
  /// - define it in an instance of geometry::ProximityProperties using
  ///   the function geometry::AddCompliantHydroelasticProperties() and
  ///   geometry::AddCompliantHydroelasticPropertiesForHalfSpace(), or
  /// - define it in an input URDF/SDFormat file as detailed here:
  ///   @ref tag_drake_hydroelastic_modulus.
  ///
  /// With the effective properties of the pair defined as above, the
  /// hydroelastic model pressure field is computed according to:
  /// <pre>
  ///   p(x) = E⋅ε(x)⋅(1 - d⋅vₙ(x))₊
  /// </pre>
  /// where we defined the effective strain: <pre>
  ///   ε(x) = εᵃ(x) + εᵇ(x)
  /// </pre>
  /// which relates to the quasi-static pressure field p₀(x) (i.e. when velocity
  /// is neglected) by: <pre>
  ///   p₀(x) = E⋅ε(x) = Eᵃ⋅εᵃ(x) = Eᵇ⋅εᵇ(x)
  /// </pre>
  /// that is, the hydroelastic model computes the contact patch assuming
  /// quasi-static equilibrium.
  /// The separation speed `vₙ(x)` is computed as the component in the
  /// direction of the contact surface's normal `n̂(x)` of the relative velocity
  /// between points `Ax` and `Bx` at point `x` instantaneously moving with body
  /// frames A and B respectively, i.e. `vₙ(x) = ᴬˣvᴮˣ⋅n̂(x)`, where the normal
  /// `n̂(x)` points from body A into body B.
  ///
  /// [Elandt 2019] R. Elandt, E. Drumwright, M. Sherman, and A. Ruina. A
  ///   pressure field model for fast, robust approximation of net contact force
  ///   and moment between nominally rigid objects. Proc. IEEE/RSJ Intl. Conf.
  ///   on Intelligent Robots and Systems (IROS), 2019.
  ///
  /// @anchor mbp_penalty_method
  ///                   #### Penalty method point contact
  ///
  /// Currently %MultibodyPlant uses a rigid contact model that is, bodies in
  /// the model are infinitely stiff or ideal rigid bodies. Therefore, the
  /// mathematical description of the rigid contact model needs to include
  /// non-penetration constraints among bodies in the formulation. There are
  /// several numerical methods to impose and solve these constraints.
  /// In a penalty method approach, we allow for a certain amount of
  /// interpenetration and we compute contact forces according to a simple law
  /// of the form: <pre>
  ///   fₙ = k(1+dẋ)x
  /// </pre>
  /// where the normal contact force `fₙ` is made a continuous function of the
  /// penetration distance x between the bodies (defined to be positive when
  /// the bodies are in contact) and the penetration distance rate ẋ (with ẋ >
  /// 0 meaning the penetration distance is increasing and therefore the
  /// interpenetration between the bodies is also increasing).  k and d are the
  /// combined penalty method coefficients for stiffness and dissipation, given
  /// a pair of colliding geometries. Dissipation is modeled using a Hunt &
  /// Crossley model of dissipation, see
  /// @ref mbp_dissipation_model "Modeling Dissipation" for
  /// details.  For flexibility of parameterization, stiffness and dissipation
  /// are set on a per-geometry basis
  /// (@ref accessing_contact_properties). Given two geometries with individual
  /// stiffness and dissipation parameters (k₁, d₁) and (k₂, d₂), we define the
  /// rule for combined stiffness (k) and dissipation (d) as: <pre>
  ///     k = (k₁⋅k₂)/(k₁+k₂)
  ///     d = (k₂/(k₁+k₂))⋅d₁ + (k₁/(k₁+k₂))⋅d₂
  /// </pre>
  /// These parameters are optional for each geometry. For any geometry not
  /// assigned these parameters by a user Pre-Finalize, %MultibodyPlant will
  /// assign default values such that the combined parameters of two geometries
  /// with default values match those estimated using the user-supplied
  /// "penetration allowance", as described below.
  ///
  /// These are ad-hoc parameters which need to be tuned as a trade-off between:
  /// - The accuracy of the numerical approximation to rigid contact, which
  ///   requires a stiffness that approaches infinity, and
  /// - the computational cost of the numerical integration, which will
  ///   require smaller time steps for stiffer systems.
  ///
  /// There is no exact procedure for choosing these coefficients, and
  /// estimating them manually can be cumbersome since in general they will
  /// depend on the scale of the problem including masses, speeds and even
  /// body sizes. However, %MultibodyPlant aids the estimation of these
  /// coefficients using a heuristic function based on a user-supplied
  /// "penetration allowance", see set_penetration_allowance(). The penetration
  /// allowance is a number in meters that specifies the order of magnitude of
  /// the average penetration between bodies in the system that the user is
  /// willing to accept as reasonable for the problem being solved. For
  /// instance, in the robotics manipulation of ordinary daily objects the user
  /// might set this number to 1 millimeter. However, the user might want to
  /// increase it for the simulation of heavy walking robots for which an
  /// allowance of 1 millimeter would result in a very stiff system.
  ///
  /// As for the dissipation coefficient in the simple law above,
  /// %MultibodyPlant chooses the dissipation coefficient d to model inelastic
  /// collisions and therefore sets it so that the penetration distance x
  /// behaves as a critically damped oscillator. That is, at the limit of ideal
  /// rigid contact (very stiff penalty coefficient k or equivalently the
  /// penetration allowance goes to zero), this method behaves as a unilateral
  /// constraint on the penetration distance, which models a perfect inelastic
  /// collision. For most applications, such as manipulation and walking, this
  /// is the desired behavior.
  ///
  /// When set_penetration_allowance() is called, %MultibodyPlant will estimate
  /// reasonable penalty method coefficients as a function of the input
  /// penetration allowance. Users will want to run their simulation a number of
  /// times and assess they are satisfied with the level of inter-penetration
  /// actually observed in the simulation; if the observed penetration is too
  /// large, the user will want to set a smaller penetration allowance. If the
  /// system is too stiff and the time integration requires very small time
  /// steps while at the same time the user can afford larger
  /// inter-penetrations, the user will want to increase the penetration
  /// allowance. Typically, the observed penetration will be
  /// proportional to the penetration allowance. Thus scaling the penetration
  /// allowance by say a factor of 0.5, would typically results in
  /// inter-penetrations being reduced by the same factor of 0.5.
  /// In summary, users should choose the largest penetration allowance that
  /// results in inter-penetration levels that are acceptable for the particular
  /// application (even when in theory this penetration should be zero for
  /// perfectly rigid bodies.)
  ///
  /// For a given penetration allowance, the contact interaction that takes two
  /// bodies with a non-zero approaching velocity to zero approaching velocity,
  /// takes place in a finite amount of time (for ideal rigid contact this time
  /// is zero.) A good estimate of this time period is given by a call to
  /// get_contact_penalty_method_time_scale(). Users might want to query this
  /// value to either set the maximum time step in error-controlled time
  /// integration or to set the time step for fixed time step integration.
  /// As a guidance, typical fixed time step integrators will become unstable
  /// for time steps larger than about a tenth of this time scale.
  ///
  /// For further details on contact modeling in Drake, please refer to the
  /// section @ref drake_contacts "Contact Modeling in Drake" of our
  /// documentation.
  ///
  /// @anchor mbp_dissipation_model
  ///                   #### Modeling Dissipation
  ///
  /// We use a dissipation model inspired by the model in
  /// [Hunt and Crossley, 1975], parameterized by a dissipation constant with
  /// units of inverse of velocity, i.e. `s/m`.
  ///
  /// To be more precise, compliant point contact forces are modeled as a
  /// function of state x: <pre>
  ///   f(x) = f₀(x)⋅(1 - d⋅vₙ(x))₊
  /// </pre>
  /// where here `f₀(x)` denotes the elastic forces, vₙ(x) is the contact
  /// velocity in the normal direction (negative when objects approach) and
  /// `(a)₊` denotes "the positive part of a". The model parameter `d ` is the
  /// Hunt & Crossley dissipation constant, in s/m. The Hunt & Crossley term
  /// `(1 - d⋅vₙ(x))₊` models the effect of dissipation due to deformation.
  ///
  /// Similarly, Drake's hydroelastic contact model incorporates dissipation at
  /// the stress level, rather than forces. That is, pressure `p(x)` at a
  /// specific point on the contact surface is replaces the force `f(x)` in the
  /// point contact model: <pre>
  ///   p(x) = p₀(x)⋅(1 - d⋅vₙ(x))₊
  /// </pre>
  /// where `p₀(x)` is the (elastic) hydroelastic pressure and once more the
  /// term `(1 - d⋅vₙ(x))₊` models Hunt & Crossley dissipation.
  ///
  /// [Hunt and Crossley 1975] Hunt, KH and Crossley, FRE, 1975. Coefficient
  ///   of restitution interpreted as damping in vibroimpact. Journal of Applied
  ///   Mechanics, vol. 42, pp. 440–445.
  ///
  /// @{

  /// Sets the contact model to be used by `this` %MultibodyPlant, see
  /// ContactModel for available options.
  /// The default contact model is ContactModel::kHydroelasticWithFallback.
  /// @throws std::exception iff called post-finalize.
  void set_contact_model(ContactModel model);

  /// Sets the contact solver type used for discrete %MultibodyPlant models.
  /// @warning This function is a no-op for continuous models (when
  /// is_discrete() is false.)
  /// @throws std::exception iff called post-finalize.
  void set_discrete_contact_solver(DiscreteContactSolver contact_solver);

  /// Returns the contact solver type used for discrete %MultibodyPlant models.
  DiscreteContactSolver get_discrete_contact_solver() const;

  /// Non-negative dimensionless number typically in the range [0.0, 1.0],
  /// though larger values are allowed even if uncommon. This parameter controls
  /// the "near rigid" regime of the SAP solver, β in section V.B of [Castro et
  /// al., 2021]. It essentially controls a threshold value for the maximum
  /// amount of stiffness SAP can handle robustly. Beyond this value, stiffness
  /// saturates as explained in [Castro et al., 2021]. A value of 1.0 is a
  /// conservative choice to avoid ill-conditioning that might lead to softer
  /// than expected contact. If this is your case, consider turning off this
  /// approximation by setting this parameter to zero. For difficult cases where
  /// ill-conditioning is a problem, a small but non-zero number can be used,
  /// e.g. 1.0e-3.
  /// @throws std::exception if near_rigid_threshold is negative.
  /// @throws std::exception if called post-finalize.
  void set_sap_near_rigid_threshold(
      double near_rigid_threshold =
          MultibodyPlantConfig{}.sap_near_rigid_threshold);

  /// @returns the SAP near rigid regime threshold.
  /// @see See set_sap_near_rigid_threshold().
  double get_sap_near_rigid_threshold() const;

  /// Return the default value for contact representation, given the desired
  /// time step. Discrete systems default to use polygons; continuous systems
  /// default to use triangles.
  static geometry::HydroelasticContactRepresentation
  GetDefaultContactSurfaceRepresentation(double time_step) {
    // Maintainers should keep this function consistent with defaults chosen in
    // MultibodyPlantConfig.
    if (time_step == 0.0) {
      return geometry::HydroelasticContactRepresentation::kTriangle;
    }
    return geometry::HydroelasticContactRepresentation::kPolygon;
  }

  /// Sets the representation of contact surfaces to be used by `this`
  /// %MultibodyPlant. See geometry::HydroelasticContactRepresentation for
  /// available options. See GetDefaultContactSurfaceRepresentation() for
  /// explanation of default values.
  void set_contact_surface_representation(
      geometry::HydroelasticContactRepresentation representation) {
    contact_surface_representation_ = representation;
  }

  /// Gets the current representation of contact surfaces used by `this`
  /// %MultibodyPlant.
  geometry::HydroelasticContactRepresentation
  get_contact_surface_representation() const {
    return contact_surface_representation_;
  }

  /// Sets whether to apply collision filters to topologically adjacent bodies
  /// at Finalize() time.  Filters are applied when there exists a joint
  /// between bodies, except in the case of 6-dof joints or joints in which the
  /// parent body is `world`.
  /// @throws std::exception iff called post-finalize.
  void set_adjacent_bodies_collision_filters(bool value) {
    DRAKE_MBP_THROW_IF_FINALIZED();
    adjacent_bodies_collision_filters_ = value;
  }

  /// Returns whether to apply collision filters to topologically adjacent
  /// bodies at Finalize() time.
  bool get_adjacent_bodies_collision_filters() const {
    return adjacent_bodies_collision_filters_;
  }

  /// For use only by advanced developers wanting to try out their custom time
  /// stepping strategies, including contact resolution.
  ///
  /// @experimental
  ///
  /// With this method MultibodyPlant takes ownership of `manager`.
  ///
  /// @note Setting a contact manager bypasses the mechanism to set a different
  /// contact solver with SetContactSolver(). Use only one of these two
  /// experimental mechanisms but never both.
  ///
  /// @param manager
  ///   After this call the new manager is used to advance discrete states.
  /// @pre this %MultibodyPlant is discrete.
  /// @pre manager != nullptr.
  /// @throws std::exception if called pre-finalize. See Finalize().
  /// @note `this` MultibodyPlant will no longer support scalar conversion to or
  /// from symbolic::Expression after a call to this method.
  void SetDiscreteUpdateManager(
      std::unique_ptr<internal::DiscreteUpdateManager<T>> manager);

  /// For use only by advanced developers wanting to try out their new physical
  /// models.
  ///
  /// @experimental
  ///
  /// With this method MultibodyPlant takes ownership of `model` and
  /// calls its DeclareSystemResources() method at Finalize(), giving specific
  /// physical model implementations a chance to declare the system resources it
  /// needs. Each type of PhysicalModel can be added at most once.
  ///
  /// @param model After this call the model is owned by `this` MultibodyPlant.
  /// @pre model != nullptr.
  /// @throws std::exception if called post-finalize. See Finalize().
  /// @note `this` MultibodyPlant will no longer support scalar conversion to or
  /// from symbolic::Expression after a call to this method.
  void AddPhysicalModel(std::unique_ptr<PhysicalModel<T>> model);

  /// Returns a vector of pointers to all physical models registered with this
  /// %MultibodyPlant. For use only by advanced developers.
  ///
  /// @experimental
  std::vector<const PhysicalModel<T>*> physical_models() const;

  // TODO(amcastro-tri): per work in #13064, we should reconsider whether to
  // deprecate/remove this method altogether or at least promote to proper
  // camel case per GSG.
  /// Sets the penetration allowance used to estimate the coefficients in the
  /// penalty method used to impose non-penetration among bodies. Refer to the
  /// section @ref mbp_penalty_method "Contact by penalty method" for further
  /// details.
  ///
  /// @throws std::exception if penetration_allowance is not positive.
  void set_penetration_allowance(
      double penetration_allowance =
          MultibodyPlantConfig{}.penetration_allowance);

  /// Returns a time-scale estimate `tc` based on the requested penetration
  /// allowance δ set with set_penetration_allowance().
  /// For the penalty method in use to enforce non-penetration, this time scale
  /// relates to the time it takes the relative normal velocity between two
  /// bodies to go to zero. This time scale `tc` is artificially introduced by
  /// the penalty method and goes to zero in the limit to ideal rigid contact.
  /// Since numerical integration methods for continuum systems must be able to
  /// resolve a system's dynamics, the time step used by an integrator must in
  /// general be much smaller than the time scale `tc`. How much smaller will
  /// depend on the details of the problem and the convergence characteristics
  /// of the integrator and should be tuned appropriately.
  /// Another factor to take into account for setting up the simulation's time
  /// step is the speed of the objects in your simulation. If `vn` represents a
  /// reference velocity scale for the normal relative velocity between bodies,
  /// the new time scale `tn = δ / vn` represents the time it would take for the
  /// distance between two bodies approaching with relative normal velocity `vn`
  /// to decrease by the penetration_allowance δ. In this case a user should
  /// choose a time step for simulation that can resolve the smallest of the two
  /// time scales `tc` and `tn`.
  double get_contact_penalty_method_time_scale() const {
    DRAKE_MBP_THROW_IF_NOT_FINALIZED();
    return penalty_method_contact_parameters_.time_scale;
  }

  /// @anchor mbp_stribeck_model
  /// ###               Stribeck model of friction
  ///
  /// Currently %MultibodyPlant uses the Stribeck approximation to model dry
  /// friction. The Stribeck model of friction is an approximation to Coulomb's
  /// law of friction that allows using continuous time integration without the
  /// need to specify complementarity constraints. While this results in a
  /// simpler model immediately tractable with standard numerical methods for
  /// integration of ODE's, it often leads to stiff dynamics that require
  /// an explicit integrator to take very small time steps. It is therefore
  /// recommended to use error controlled integrators when using this model or
  /// the discrete time stepping (see @ref time_advancement_strategy
  /// "Choice of Time Advancement Strategy").
  /// See @ref stribeck_approximation for a detailed discussion of the Stribeck
  /// model.
  ///
  /// Sets the stiction tolerance `v_stiction` for the Stribeck model, where
  /// `v_stiction` must be specified in m/s (meters per second.)
  /// `v_stiction` defaults to a value of 1 millimeter per second.
  /// In selecting a value for `v_stiction`, you must ask yourself the question,
  /// "When two objects are ostensibly in stiction, how much slip am I willing
  /// to allow?" There are two opposing design issues in picking a value for
  /// vₛ. On the one hand, small values of vₛ make the problem numerically
  /// stiff during stiction, potentially increasing the integration cost. On the
  /// other hand, it should be picked to be appropriate for the scale of the
  /// problem. For example, a car simulation could allow a "large" value for vₛ
  /// of 1 cm/s (1×10⁻² m/s), but reasonable stiction for grasping a 10 cm box
  /// might require limiting residual slip to 1×10⁻³ m/s or less. Ultimately,
  /// picking the largest viable value will allow your simulation to run
  /// faster and more robustly.
  /// Note that `v_stiction` is the slip velocity that we'd have when we are at
  /// edge of the friction cone. For cases when the friction force is well
  /// within the friction cone the slip velocity will always be smaller than
  /// this value.
  /// See also @ref stribeck_approximation.
  /// @throws std::exception if `v_stiction` is non-positive.
  void set_stiction_tolerance(
      double v_stiction = MultibodyPlantConfig{}.stiction_tolerance) {
    friction_model_.set_stiction_tolerance(v_stiction);
  }

  /// @returns the stiction tolerance parameter, in m/s.
  /// @see set_stiction_tolerance.
  double stiction_tolerance() const {
    return friction_model_.stiction_tolerance();
  }

  /// @} <!-- Contact modeling -->

  /// @anchor mbp_state_accessors_and_mutators
  /// @name               State accessors and mutators
  /// The following state methods allow getting and setting the kinematic state
  /// variables `[q; v]`, where `q` is the vector of generalized positions and
  /// `v` is the vector of generalized velocities. The state resides in a
  /// @ref systems::Context "Context" that is supplied
  /// as the first argument to every method.
  ///
  /// @note State vectors for the full system are returned as live references
  /// into the Context, not independent copies. In contrast, state vectors
  /// for individual model instances are returned as copies because the state
  /// associated with a model instance is generally not contiguous in a Context.
  ///
  /// There are also utilities for accessing and mutating portions of state
  /// or actuation arrays corresponding to just a single model instance.
  /// @{

  /// Returns a const vector reference `[q; v]` to the generalized positions q
  /// and generalized velocities v in a given Context.
  /// @note This method returns a reference to existing data, exhibits constant
  ///       i.e., O(1) time complexity, and runs very quickly.
  /// @throws std::exception if `context` does not correspond to the Context
  /// for a multibody model.
  Eigen::VectorBlock<const VectorX<T>> GetPositionsAndVelocities(
      const systems::Context<T>& context) const {
    this->ValidateContext(context);
    return internal_tree().get_positions_and_velocities(context);
  }

  /// Returns a vector `[q; v]` containing the generalized positions q and
  /// generalized velocities v of a specified model instance in a given Context.
  /// @note Returns a dense vector of dimension
  ///       `num_positions(model_instance) + num_velocities(model_instance)`
  ///       associated with `model_instance` by copying from `context`.
  /// @throws std::exception if `context` does not correspond to the Context
  /// for a multibody model or `model_instance` is invalid.
  VectorX<T> GetPositionsAndVelocities(
      const systems::Context<T>& context,
      ModelInstanceIndex model_instance) const {
    this->ValidateContext(context);
    return internal_tree().GetPositionsAndVelocities(context, model_instance);
  }

  /// (Advanced) Populates output vector qv_out representing the generalized
  /// positions q and generalized velocities v of a specified model instance
  /// in a given Context.
  /// @note qv_out is a dense vector of dimensions
  ///       `num_positions(model_instance) + num_velocities(model_instance)`
  ///       associated with `model_instance` and is populated by copying from
  ///       `context`.
  /// @note This function is guaranteed to allocate no heap.
  /// @throws std::exception if `context` does not correspond to the Context
  ///         for a multibody model or `model_instance` is invalid.
  /// @throws std::exception if qv_out does not have size
  ///         `num_positions(model_instance) + num_velocities(model_instance)`
  void GetPositionsAndVelocities(const systems::Context<T>& context,
                                 ModelInstanceIndex model_instance,
                                 EigenPtr<VectorX<T>> qv_out) const {
    this->ValidateContext(context);
    internal_tree().GetPositionsAndVelocities(context, model_instance, qv_out);
  }

  /// (Advanced -- **see warning**) Returns a mutable vector reference `[q; v]`
  /// to the generalized positions q and generalized velocities v in a given
  /// Context.
  /// @warning Cache invalidation will occur when this is called but not if you
  ///          subsequently write through the returned object. You should use
  ///          SetPositionsAndVelocities() instead unless you are
  ///          fully aware of the interactions with the caching mechanism (see
  ///          @ref dangerous_get_mutable).
  /// @throws std::exception if `context` is nullptr or if it does not
  /// correspond to the context for a multibody model.
  DRAKE_DEPRECATED(
      "2024-02-01",
      "Use GetPositionsAndVelocities() for constant access and "
      "SetPositionsAndVelocities() to set the positions and velocities.")
  Eigen::VectorBlock<VectorX<T>> GetMutablePositionsAndVelocities(
      systems::Context<T>* context) const {
    this->ValidateContext(context);
    return internal_tree().GetMutablePositionsAndVelocities(context);
  }

  /// Sets generalized positions q and generalized velocities v in a given
  /// Context from a given vector [q; v]. Prefer this method over
  /// GetMutablePositionsAndVelocities().
  /// @throws std::exception if `context` is nullptr, if `context` does
  /// not correspond to the context for a multibody model, or if the length of
  /// `q_v` is not equal to `num_positions() + num_velocities()`.
  void SetPositionsAndVelocities(
      systems::Context<T>* context,
      const Eigen::Ref<const VectorX<T>>& q_v) const {
    this->ValidateContext(context);
    DRAKE_THROW_UNLESS(q_v.size() == (num_positions() + num_velocities()));
    internal_tree().GetMutablePositionsAndVelocities(context) = q_v;
  }

  /// Sets generalized positions q and generalized velocities v from a given
  /// vector [q; v] for a specified model instance in a given Context.
  /// @throws std::exception if `context` is nullptr, if `context` does
  /// not correspond to the Context for a multibody model, if the model instance
  /// index is invalid, or if the length of `q_v` is not equal to
  /// `num_positions(model_instance) + num_velocities(model_instance)`.
  void SetPositionsAndVelocities(
      systems::Context<T>* context, ModelInstanceIndex model_instance,
      const Eigen::Ref<const VectorX<T>>& q_v) const {
    this->ValidateContext(context);
    DRAKE_THROW_UNLESS(q_v.size() == (num_positions(model_instance) +
                                      num_velocities(model_instance)));
    internal_tree().SetPositionsAndVelocities(model_instance, q_v, context);
  }

  /// Returns a const vector reference to the vector of generalized positions
  /// q in a given Context.
  /// @note This method returns a reference to existing data, exhibits constant
  ///       i.e., O(1) time complexity, and runs very quickly.
  /// @throws std::exception if `context` does not correspond to the Context for
  /// a multibody model.
  Eigen::VectorBlock<const VectorX<T>> GetPositions(
      const systems::Context<T>& context) const {
    this->ValidateContext(context);
    return internal_tree().get_positions(context);
  }

  /// Returns a vector containing the generalized positions q of a specified
  /// model instance in a given Context.
  /// @note Returns a dense vector of dimension `num_positions(model_instance)`
  ///       associated with `model_instance` by copying from `context`.
  /// @throws std::exception if `context` does not correspond to the Context
  /// for a multibody model or `model_instance` is invalid.
  VectorX<T> GetPositions(const systems::Context<T>& context,
                          ModelInstanceIndex model_instance) const {
    this->ValidateContext(context);
    return internal_tree().GetPositionsFromArray(
        model_instance, internal_tree().get_positions(context));
  }

  /// (Advanced) Populates output vector q_out with the generalized positions q
  /// of a specified model instance in a given Context.
  /// @note q_out is a dense vector of dimension
  ///       `num_positions(model_instance)' associated with `model_instance`
  ///       and is populated by copying from `context`.
  /// @note This function is guaranteed to allocate no heap.
  /// @throws std::exception if `context` does not correspond to the Context
  ///         for a multibody model or `model_instance` is invalid.
  void GetPositions(const systems::Context<T>& context,
                    ModelInstanceIndex model_instance,
                    EigenPtr<VectorX<T>> q_out) const {
    this->ValidateContext(context);
    internal_tree().GetPositionsFromArray(
        model_instance, internal_tree().get_positions(context), q_out);
  }

  /// (Advanced -- **see warning**) Returns a mutable vector reference to the
  /// generalized positions q in a given Context.
  /// @warning Cache invalidation will occur when this is called but not
  ///          if you subsequently write through the returned object. You
  ///          should use SetPositions() instead unless you are fully aware
  ///          of the possible interactions with the caching mechanism (see
  ///          @ref dangerous_get_mutable).
  /// @throws std::exception if the `context` is nullptr or if it does not
  /// correspond to the Context for a multibody model.
  DRAKE_DEPRECATED("2024-02-01",
                   "Use GetPositions() for constant access and SetPositions() "
                   "to set positions.")
  Eigen::VectorBlock<VectorX<T>> GetMutablePositions(
      systems::Context<T>* context) const {
    this->ValidateContext(context);
    return internal_tree().GetMutablePositions(context);
  }

  /// (Advanced) Returns a mutable vector reference to the generalized positions
  /// q in a given State.
  /// @note This method returns a reference to existing data, exhibits constant
  ///       i.e., O(1) time complexity, and runs very quickly. No cache
  ///       invalidation occurs.
  /// @throws std::exception if the `state` is nullptr or if `context` does
  ///         not correspond to the Context for a multibody model.
  /// @pre `state` comes from this multibody model.
  DRAKE_DEPRECATED("2024-02-01",
                   "Use GetPositions() for constant access and SetPositions() "
                   "to set positions.")
  Eigen::VectorBlock<VectorX<T>> GetMutablePositions(
      const systems::Context<T>& context, systems::State<T>* state) const {
    this->ValidateContext(context);
    this->ValidateCreatedForThisSystem(state);
    return internal_tree().get_mutable_positions(state);
  }

  /// Sets the generalized positions q in a given Context from a given vector.
  /// Prefer this method over GetMutablePositions().
  /// @throws std::exception if `context` is nullptr, if `context` does not
  /// correspond to the Context for a multibody model, or if the length of `q`
  /// is not equal to `num_positions()`.
  void SetPositions(systems::Context<T>* context,
                    const Eigen::Ref<const VectorX<T>>& q) const {
    this->ValidateContext(context);
    DRAKE_THROW_UNLESS(q.size() == num_positions());
    internal_tree().GetMutablePositions(context) = q;
  }

  /// Sets the generalized positions q for a particular model instance in a
  /// given Context from a given vector.
  /// @throws std::exception if the `context` is nullptr, if `context` does
  /// not correspond to the Context for a multibody model, if the model instance
  /// index is invalid, or if the length of `q_instance` is not equal to
  /// `num_positions(model_instance)`.
  void SetPositions(systems::Context<T>* context,
                    ModelInstanceIndex model_instance,
                    const Eigen::Ref<const VectorX<T>>& q_instance) const {
    this->ValidateContext(context);
    DRAKE_THROW_UNLESS(q_instance.size() == num_positions(model_instance));
    Eigen::VectorBlock<VectorX<T>> q =
        internal_tree().GetMutablePositions(context);
    internal_tree().SetPositionsInArray(model_instance, q_instance, &q);
  }

  /// (Advanced) Sets the generalized positions q for a particular model
  /// instance in a given State from a given vector.
  /// @note No cache invalidation occurs.
  /// @throws std::exception if the `context` is nullptr, if `context` does
  /// not correspond to the Context for a multibody model, if the model instance
  /// index is invalid, or if the length of `q_instance` is not equal to
  /// `num_positions(model_instance)`.
  /// @pre `state` comes from this MultibodyPlant.
  void SetPositions(const systems::Context<T>& context,
                    systems::State<T>* state, ModelInstanceIndex model_instance,
                    const Eigen::Ref<const VectorX<T>>& q_instance) const {
    this->ValidateContext(context);
    this->ValidateCreatedForThisSystem(state);
    DRAKE_THROW_UNLESS(q_instance.size() == num_positions(model_instance));
    Eigen::VectorBlock<VectorX<T>> q =
        internal_tree().get_mutable_positions(state);
    internal_tree().SetPositionsInArray(model_instance, q_instance, &q);
  }

  /// Gets the default positions for the plant, which can be changed via
  /// SetDefaultPositions().
  /// @throws std::exception if the plant is not finalized.
  VectorX<T> GetDefaultPositions() const;

  /// Gets the default positions for the plant for a given model instance,
  /// which can be changed via SetDefaultPositions().
  /// @throws std::exception if the plant is not finalized, or if the
  /// model_instance is invalid,
  VectorX<T> GetDefaultPositions(ModelInstanceIndex model_instance) const;

  /// Sets the default positions for the plant.  Calls to CreateDefaultContext
  /// or SetDefaultContext/SetDefaultState will return a Context populated with
  /// these position values. They have no other effects on the dynamics of the
  /// system.
  /// @throws std::exception if the plant is not finalized or if q is
  /// not of size num_positions().
  void SetDefaultPositions(const Eigen::Ref<const Eigen::VectorXd>& q);

  /// Sets the default positions for the model instance.  Calls to
  /// CreateDefaultContext or SetDefaultContext/SetDefaultState will return a
  /// Context populated with these position values. They have no other effects
  /// on the dynamics of the system.
  /// @throws std::exception if the plant is not
  /// finalized, if the model_instance is invalid, or if the length of
  /// `q_instance` is not equal to `num_positions(model_instance)`.
  void SetDefaultPositions(ModelInstanceIndex model_instance,
                           const Eigen::Ref<const Eigen::VectorXd>& q_instance);

  /// Returns a const vector reference to the generalized velocities v in a
  /// given Context.
  /// @note This method returns a reference to existing data, exhibits constant
  ///       i.e., O(1) time complexity, and runs very quickly.
  /// @throws std::exception if `context` does not correspond to the Context
  /// for a multibody model.
  Eigen::VectorBlock<const VectorX<T>> GetVelocities(
      const systems::Context<T>& context) const {
    this->ValidateContext(context);
    return internal_tree().get_velocities(context);
  }

  /// Returns a vector containing the generalized velocities v of a specified
  /// model instance in a given Context.
  /// @note returns a dense vector of dimension `num_velocities(model_instance)`
  ///       associated with `model_instance` by copying from `context`.
  /// @throws std::exception if `context` does not correspond to the Context
  /// for a multibody model or `model_instance` is invalid.
  VectorX<T> GetVelocities(const systems::Context<T>& context,
                           ModelInstanceIndex model_instance) const {
    this->ValidateContext(context);
    return internal_tree().GetVelocitiesFromArray(
        model_instance, internal_tree().get_velocities(context));
  }

  /// (Advanced) Populates output vector v_out with the generalized
  /// velocities v of a specified model instance in a given Context.
  /// @note v_out is a dense vector of dimension
  ///       `num_velocities(model_instance)` associated with `model_instance`
  ///       and is populated by copying from `context`.
  /// @note This function is guaranteed to allocate no heap.
  /// @throws std::exception if `context` does not correspond to the Context
  ///         for a multibody model or `model_instance` is invalid.
  void GetVelocities(const systems::Context<T>& context,
                     ModelInstanceIndex model_instance,
                     EigenPtr<VectorX<T>> v_out) const {
    this->ValidateContext(context);
    internal_tree().GetVelocitiesFromArray(
        model_instance, internal_tree().get_velocities(context), v_out);
  }

  /// (Advanced -- **see warning**) Returns a mutable vector reference to the
  /// generalized velocities v in a given Context.
  /// @warning Cache invalidation will occur when this is called but not
  ///          if you subsequently write through the returned object. You
  ///          should use SetVelocities() instead unless you are fully aware
  ///          of the possible interactions with the caching mechanism (see
  ///          @ref dangerous_get_mutable).
  /// @throws std::exception if the `context` is nullptr or if it does not
  /// correspond to the Context for a multibody model.
  DRAKE_DEPRECATED("2024-02-01",
                   "Use GetVelocities() for constant access and "
                   "SetVelocities() to set velocities.")
  Eigen::VectorBlock<VectorX<T>> GetMutableVelocities(
      systems::Context<T>* context) const {
    this->ValidateContext(context);
    return internal_tree().GetMutableVelocities(context);
  }

  /// (Advanced) Returns a mutable vector reference to the generalized
  /// velocities v in a given State.
  /// @note This method returns a reference to existing data, exhibits constant
  ///       i.e., O(1) time complexity, and runs very quickly. No cache
  ///       invalidation occurs.
  /// @throws std::exception if the `state` is nullptr or if `context` does
  ///         not correspond to the Context for a multibody model.
  /// @pre `state` comes from this multibody model.
  DRAKE_DEPRECATED("2024-02-01",
                   "Use GetVelocities() for constant access and "
                   "SetVelocities() to set velocities.")
  Eigen::VectorBlock<VectorX<T>> GetMutableVelocities(
      const systems::Context<T>& context, systems::State<T>* state) const {
    this->ValidateContext(context);
    this->ValidateCreatedForThisSystem(state);
    return internal_tree().get_mutable_velocities(state);
  }

  /// Sets the generalized velocities v in a given Context from a given
  /// vector. Prefer this method over GetMutableVelocities().
  /// @throws std::exception if the `context` is nullptr, if the context does
  /// not correspond to the context for a multibody model, or if the length of
  /// `v` is not equal to `num_velocities()`.
  void SetVelocities(systems::Context<T>* context,
                     const Eigen::Ref<const VectorX<T>>& v) const {
    this->ValidateContext(context);
    DRAKE_THROW_UNLESS(v.size() == num_velocities());
    internal_tree().GetMutableVelocities(context) = v;
  }

  /// Sets the generalized velocities v for a particular model instance in a
  /// given Context from a given vector.
  /// @throws std::exception if the `context` is nullptr, if `context` does
  /// not correspond to the Context for a multibody model, if the model instance
  /// index is invalid, or if the length of `v_instance` is not equal to
  /// `num_velocities(model_instance)`.
  void SetVelocities(systems::Context<T>* context,
                     ModelInstanceIndex model_instance,
                     const Eigen::Ref<const VectorX<T>>& v_instance) const {
    this->ValidateContext(context);
    DRAKE_THROW_UNLESS(v_instance.size() == num_velocities(model_instance));
    Eigen::VectorBlock<VectorX<T>> v =
        internal_tree().GetMutableVelocities(context);
    internal_tree().SetVelocitiesInArray(model_instance, v_instance, &v);
  }

  /// (Advanced) Sets the generalized velocities v for a particular model
  /// instance in a given State from a given vector.
  /// @note No cache invalidation occurs.
  /// @throws std::exception if the `context` is nullptr, if `context` does
  /// not correspond to the Context for a multibody model, if the model instance
  /// index is invalid, or if the length of `v_instance` is not equal to
  /// `num_velocities(model_instance)`.
  /// @pre `state` comes from this MultibodyPlant.
  void SetVelocities(const systems::Context<T>& context,
                     systems::State<T>* state,
                     ModelInstanceIndex model_instance,
                     const Eigen::Ref<const VectorX<T>>& v_instance) const {
    this->ValidateContext(context);
    this->ValidateCreatedForThisSystem(state);
    DRAKE_THROW_UNLESS(v_instance.size() == num_velocities(model_instance));
    Eigen::VectorBlock<VectorX<T>> v =
        internal_tree().get_mutable_velocities(state);
    internal_tree().SetVelocitiesInArray(model_instance, v_instance, &v);
  }

  /// Sets `state` according to defaults set by the user for joints (e.g.
  /// RevoluteJoint::set_default_angle()) and free bodies
  /// (SetDefaultFreeBodyPose()). If the user does not specify defaults, the
  /// state corresponds to zero generalized positions and velocities.
  /// @throws std::exception if called pre-finalize. See Finalize().
  void SetDefaultState(const systems::Context<T>& context,
                       systems::State<T>* state) const override {
    DRAKE_MBP_THROW_IF_NOT_FINALIZED();
    this->ValidateContext(context);
    this->ValidateCreatedForThisSystem(state);
    internal_tree().SetDefaultState(context, state);
  }

  /// Assigns random values to all elements of the state, by drawing samples
  /// independently for each joint/free body (coming soon: and then
  /// solving a mathematical program to "project" these samples onto the
  /// registered system constraints). If a random distribution is not specified
  /// for a joint/free body, the default state is used.
  ///
  /// @see @ref stochastic_systems
  void SetRandomState(const systems::Context<T>& context,
                      systems::State<T>* state,
                      RandomGenerator* generator) const override {
    DRAKE_MBP_THROW_IF_NOT_FINALIZED();
    this->ValidateContext(context);
    this->ValidateCreatedForThisSystem(state);
    internal_tree().SetRandomState(context, state, generator);
  }

  /// Returns a list of string names corresponding to each element of the
  /// position vector. These strings take the form
  /// `{model_instance_name}_{joint_name}_{joint_position_suffix}`, but the
  /// prefix and suffix may optionally be withheld using @p
  /// add_model_instance_prefix and @p always_add_suffix.
  ///
  /// @param always_add_suffix (optional). If true, then the suffix is always
  /// added. If false, then the suffix is only added for joints that have more
  /// than one position (in this case, not adding would lead to ambiguity).
  ///
  /// The returned names are guaranteed to be unique if @p
  /// add_model_instance_prefix is `true` (the default).
  ///
  /// @throws std::exception if the plant is not finalized.
  std::vector<std::string> GetPositionNames(
      bool add_model_instance_prefix = true,
      bool always_add_suffix = true) const;

  /// Returns a list of string names corresponding to each element of the
  /// position vector. These strings take the form
  /// `{model_instance_name}_{joint_name}_{joint_position_suffix}`, but the
  /// prefix and suffix may optionally be withheld using @p
  /// add_model_instance_prefix and @p always_add_suffix.
  ///
  /// @param always_add_suffix (optional). If true, then the suffix is always
  /// added. If false, then the suffix is only added for joints that have more
  /// than one position (in this case, not adding would lead to ambiguity).
  ///
  /// The returned names are guaranteed to be unique.
  ///
  /// @throws std::exception if the plant is not finalized or if the @p
  /// model_instance is invalid.
  std::vector<std::string> GetPositionNames(
      ModelInstanceIndex model_instance, bool add_model_instance_prefix = false,
      bool always_add_suffix = true) const;

  /// Returns a list of string names corresponding to each element of the
  /// velocity vector. These strings take the form
  /// `{model_instance_name}_{joint_name}_{joint_velocity_suffix}`, but the
  /// prefix and suffix may optionally be withheld using @p
  /// add_model_instance_prefix and @p always_add_suffix.
  ///
  /// @param always_add_suffix (optional). If true, then the suffix is always
  /// added. If false, then the suffix is only added for joints that have more
  /// than one position (in this case, not adding would lead to ambiguity).
  ///
  /// The returned names are guaranteed to be unique if @p
  /// add_model_instance_prefix is `true` (the default).
  ///
  /// @throws std::exception if the plant is not finalized.
  std::vector<std::string> GetVelocityNames(
      bool add_model_instance_prefix = true,
      bool always_add_suffix = true) const;

  /// Returns a list of string names corresponding to each element of the
  /// velocity vector. These strings take the form
  /// `{model_instance_name}_{joint_name}_{joint_velocity_suffix}`, but the
  /// prefix and suffix may optionally be withheld using @p
  /// add_model_instance_prefix and @p always_add_suffix.
  ///
  /// @param always_add_suffix (optional). If true, then the suffix is always
  /// added. If false, then the suffix is only added for joints that have more
  /// than one position (in this case, not adding would lead to ambiguity).
  ///
  /// The returned names are guaranteed to be unique.
  ///
  /// @throws std::exception if the plant is not finalized or if the
  /// @p model_instance is invalid.
  std::vector<std::string> GetVelocityNames(
      ModelInstanceIndex model_instance, bool add_model_instance_prefix = false,
      bool always_add_suffix = true) const;

  /// Returns a list of string names corresponding to each element of the
  /// multibody state vector. These strings take the form
  /// `{model_instance_name}_{joint_name}_{joint_position_suffix |
  /// joint_velocity_suffix}`, but the prefix may optionally be withheld using
  /// @p add_model_instance_prefix.
  ///
  /// The returned names are guaranteed to be unique if @p
  /// add_model_instance_prefix is `true` (the default).
  ///
  /// @throws std::exception if the plant is not finalized.
  std::vector<std::string> GetStateNames(
      bool add_model_instance_prefix = true) const;

  /// Returns a list of string names corresponding to each element of the
  /// multibody state vector. These strings take the form
  /// `{model_instance_name}_{joint_name}_{joint_position_suffix |
  /// joint_velocity_suffix}`, but the prefix may optionally be withheld using
  /// @p add_model_instance_prefix.
  ///
  /// The returned names are guaranteed to be unique.
  ///
  /// @throws std::exception if the plant is not finalized or if the @p
  /// model_instance is invalid.
  std::vector<std::string> GetStateNames(
      ModelInstanceIndex model_instance,
      bool add_model_instance_prefix = false) const;

  /// Returns a list of string names corresponding to each element of the
  /// actuation vector. These strings take the form
  /// `{model_instance_name}_{joint_actuator_name}`, but the prefix may
  /// optionally be withheld using @p add_model_instance_prefix.
  ///
  /// The returned names are guaranteed to be unique if @p
  /// add_model_instance_prefix is `true` (the default).
  ///
  /// @throws std::exception if the plant is not finalized.
  std::vector<std::string> GetActuatorNames(
      bool add_model_instance_prefix = true) const;

  /// Returns a list of string names corresponding to each element of the
  /// actuation vector. These strings take the form
  /// `{model_instance_name}_{joint_actuator_name}`, but the prefix may
  /// optionally be withheld using @p add_model_instance_prefix.
  ///
  /// The returned names are guaranteed to be unique.
  ///
  /// @throws std::exception if the plant is not finalized or if the
  /// @p model_instance is invalid.
  std::vector<std::string> GetActuatorNames(
      ModelInstanceIndex model_instance,
      bool add_model_instance_prefix = false) const;

  /// Returns a vector of actuation values for `model_instance` from a vector
  /// `u` of actuation values for the entire plant model. Refer to @ref
  /// mbp_actuation "Actuation" for further details.
  /// @param[in] u Actuation values for the entire model, indexed by
  /// @ref JointActuatorIndex.
  /// @returns Actuation values for `model_instance`, ordered by monotonically
  /// increasing @ref JointActuatorIndex.
  /// @throws std::exception if `u` is not of size
  /// MultibodyPlant::num_actuated_dofs().
  VectorX<T> GetActuationFromArray(
      ModelInstanceIndex model_instance,
      const Eigen::Ref<const VectorX<T>>& u) const {
    return internal_tree().GetActuationFromArray(model_instance, u);
  }

  /// Given actuation values `u_instance` for the actuators in `model_instance`,
  /// this function updates the actuation vector u for the entire plant model to
  /// which this actuator belongs to. Refer to @ref mbp_actuation "Actuation"
  /// for further details.
  /// @param[in] u_instance Actuation values for the model instance. Values are
  ///   ordered by monotonically increasing @ref JointActuatorIndex within the
  ///   model instance.
  /// @param[in,out] u Actuation values for the entire plant model, indexed by
  ///   @ref JointActuatorIndex. Only values corresponding to `model_instance`
  ///   are changed.
  /// @throws std::exception if the size of `u_instance` is not equal to the
  ///   number of actuation inputs for the joints of `model_instance`.
  void SetActuationInArray(ModelInstanceIndex model_instance,
                           const Eigen::Ref<const VectorX<T>>& u_instance,
                           EigenPtr<VectorX<T>> u) const {
    DRAKE_DEMAND(u != nullptr);
    internal_tree().SetActuationInArray(model_instance, u_instance, u);
  }

  /// Returns a vector of generalized positions for `model_instance` from a
  /// vector `q_array` of generalized positions for the entire model
  /// model.  This method throws an exception if `q` is not of size
  /// MultibodyPlant::num_positions().
  VectorX<T> GetPositionsFromArray(
      ModelInstanceIndex model_instance,
      const Eigen::Ref<const VectorX<T>>& q) const {
    return internal_tree().GetPositionsFromArray(model_instance, q);
  }

  /// (Advanced) Populates output vector q_out and with the generalized
  /// positions for `model_instance` from a vector `q` of generalized
  /// positions for the entire model.  This method throws an exception
  /// if `q` is not of size MultibodyPlant::num_positions().
  void GetPositionsFromArray(ModelInstanceIndex model_instance,
                             const Eigen::Ref<const VectorX<T>>& q,
                             EigenPtr<VectorX<T>> q_out) const {
    internal_tree().GetPositionsFromArray(model_instance, q, q_out);
  }

  /// Sets the vector of generalized positions for `model_instance` in
  /// `q` using `q_instance`, leaving all other elements in the array
  /// untouched. This method throws an exception if `q` is not of size
  /// MultibodyPlant::num_positions() or `q_instance` is not of size
  /// `MultibodyPlant::num_positions(model_instance)`.
  void SetPositionsInArray(ModelInstanceIndex model_instance,
                           const Eigen::Ref<const VectorX<T>>& q_instance,
                           EigenPtr<VectorX<T>> q) const {
    DRAKE_DEMAND(q != nullptr);
    internal_tree().SetPositionsInArray(model_instance, q_instance, q);
  }

  /// Returns a vector of generalized velocities for `model_instance` from a
  /// vector `v` of generalized velocities for the entire MultibodyPlant
  /// model.  This method throws an exception if the input array is not of size
  /// MultibodyPlant::num_velocities().
  VectorX<T> GetVelocitiesFromArray(
      ModelInstanceIndex model_instance,
      const Eigen::Ref<const VectorX<T>>& v) const {
    return internal_tree().GetVelocitiesFromArray(model_instance, v);
  }

  /// (Advanced) Populates output vector v_out with the generalized
  /// velocities for `model_instance` from a vector `v` of generalized
  /// velocities for the entire model.  This method throws an exception
  /// if `v` is not of size MultibodyPlant::num_velocities().
  void GetVelocitiesFromArray(ModelInstanceIndex model_instance,
                              const Eigen::Ref<const VectorX<T>>& v,
                              EigenPtr<VectorX<T>> v_out) const {
    internal_tree().GetVelocitiesFromArray(model_instance, v, v_out);
  }

  /// Sets the vector of generalized velocities for `model_instance` in
  /// `v` using `v_instance`, leaving all other elements in the array
  /// untouched. This method throws an exception if `v` is not of size
  /// MultibodyPlant::num_velocities() or `v_instance` is not of size
  /// `MultibodyPlant::num_positions(model_instance)`.
  void SetVelocitiesInArray(ModelInstanceIndex model_instance,
                            const Eigen::Ref<const VectorX<T>>& v_instance,
                            EigenPtr<VectorX<T>> v) const {
    DRAKE_DEMAND(v != nullptr);
    internal_tree().SetVelocitiesInArray(model_instance, v_instance, v);
  }
  /// @} <!-- State accessors and mutators -->

  /// @anchor mbp_working_with_free_bodies
  /// @name                Working with free bodies
  ///
  /// A %MultibodyPlant user adds sets of Body and Joint objects to `this` plant
  /// to build a physical representation of a mechanical model.
  /// At Finalize(), %MultibodyPlant builds a mathematical representation of
  /// such system, consisting of a tree representation. In this
  /// representation each body is assigned a Mobilizer, which grants a certain
  /// number of degrees of freedom in accordance to the physical specification.
  /// In this regard, the modeling representation can be seen as a forest of
  /// tree structures each of which contains a single body at the root of the
  /// tree. If the root body has six degrees of freedom with respect to the
  /// world, it is called a "free body" (sometimes called a "floating body").
  /// A user can request the set of all free bodies with a call to
  /// GetFloatingBaseBodies(). Alternatively, a user can query whether a Body is
  /// free (floating) or not with Body::is_floating().
  /// For many applications, a user might need to work with indexes in the
  /// multibody state vector. For such applications,
  /// Body::floating_positions_start() and
  /// Body::floating_velocities_start_in_v() offer the additional level of
  /// introspection needed.
  ///
  /// It is sometimes convenient for users to perform operations on Bodies
  /// ubiquitously through the APIs of the Joint class. For that reason we
  /// implicitly construct a 6-dof joint, QuaternionFloatingJoint, for all free
  /// bodies at the time of Finalize(). Using Joint APIs to affect a free body
  /// (setting  state, changing parameters, etc.) has the same effect as using
  /// the free body APIs below. Each implicitly created joint is named the same
  /// as the free body, as reported by `Body::name()`. In the rare case that
  /// there is already some (unrelated) joint with that name, we'll prepend
  /// underscores to the name until it is unique.
  /// @{

  /// Returns the set of body indexes corresponding to the free (floating)
  /// bodies in the model, in no particular order.
  /// @throws std::exception if called pre-finalize, see Finalize().
  std::unordered_set<BodyIndex> GetFloatingBaseBodies() const;

  /// Gets the pose of a given `body` in the world frame W.
  /// @note In general getting the pose of a body in the model would involve
  /// solving the kinematics. This method allows us to simplify this process
  /// when we know the body is free in space.
  /// @throws std::exception if `body` is not a free body in the model.
  /// @throws std::exception if called pre-finalize.
  math::RigidTransform<T> GetFreeBodyPose(const systems::Context<T>& context,
                                          const Body<T>& body) const {
    this->ValidateContext(context);
    return internal_tree().GetFreeBodyPoseOrThrow(context, body);
  }

  /// Sets `context` to store the pose `X_WB` of a given `body` B in the world
  /// frame W.
  /// @note In general setting the pose and/or velocity of a body in the model
  /// would involve a complex inverse kinematics problem. This method allows us
  /// to simplify this process when we know the body is free in space.
  /// @throws std::exception if `body` is not a free body in the model.
  /// @throws std::exception if called pre-finalize.
  void SetFreeBodyPose(systems::Context<T>* context, const Body<T>& body,
                       const math::RigidTransform<T>& X_WB) const {
    this->ValidateContext(context);
    internal_tree().SetFreeBodyPoseOrThrow(body, X_WB, context);
  }

  /// Sets `state` to store the pose `X_WB` of a given `body` B in the world
  /// frame W, for a given `context` of `this` model.
  /// @note In general setting the pose and/or velocity of a body in the model
  /// would involve a complex inverse kinematics problem. This method allows us
  /// to simplify this process when we know the body is free in space.
  /// @throws std::exception if `body` is not a free body in the model.
  /// @throws std::exception if called pre-finalize.
  /// @pre `state` comes from this MultibodyPlant.
  void SetFreeBodyPose(const systems::Context<T>& context,
                       systems::State<T>* state, const Body<T>& body,
                       const math::RigidTransform<T>& X_WB) const {
    this->ValidateContext(context);
    this->ValidateCreatedForThisSystem(state);
    internal_tree().SetFreeBodyPoseOrThrow(body, X_WB, context, state);
  }

  /// Sets the default pose of `body`. If `body.is_floating()` is true, this
  /// will affect subsequent calls to SetDefaultState(); otherwise, the only
  /// effect of the call is that the value will be echoed back in
  /// GetDefaultFreeBodyPose().
  /// @param[in] body
  ///   Body whose default pose will be set.
  /// @param[in] X_WB
  ///   Default pose of the body.
  void SetDefaultFreeBodyPose(const Body<T>& body,
                              const math::RigidTransform<double>& X_WB) {
    this->mutable_tree().SetDefaultFreeBodyPose(body, X_WB);
  }

  /// Gets the default pose of `body` as set by SetDefaultFreeBodyPose(). If no
  /// pose is specified for the body, returns the identity pose.
  /// @param[in] body
  ///   Body whose default pose will be retrieved.
  math::RigidTransform<double> GetDefaultFreeBodyPose(
      const Body<T>& body) const {
    return internal_tree().GetDefaultFreeBodyPose(body);
  }

  /// Sets `context` to store the spatial velocity `V_WB` of a given `body` B in
  /// the world frame W.
  /// @note In general setting the pose and/or velocity of a body in the model
  /// would involve a complex inverse kinematics problem. This method allows us
  /// to simplify this process when we know the body is free in space.
  /// @throws std::exception if `body` is not a free body in the model.
  /// @throws std::exception if called pre-finalize.
  void SetFreeBodySpatialVelocity(systems::Context<T>* context,
                                  const Body<T>& body,
                                  const SpatialVelocity<T>& V_WB) const {
    this->ValidateContext(context);
    internal_tree().SetFreeBodySpatialVelocityOrThrow(body, V_WB, context);
  }

  /// Sets `state` to store the spatial velocity `V_WB` of a given `body` B in
  /// the world frame W, for a given `context` of `this` model.
  /// @note In general setting the pose and/or velocity of a body in the model
  /// would involve a complex inverse kinematics problem. This method allows us
  /// to simplify this process when we know the body is free in space.
  /// @throws std::exception if `body` is not a free body in the model.
  /// @throws std::exception if called pre-finalize.
  /// @pre `state` comes from this MultibodyPlant.
  void SetFreeBodySpatialVelocity(const systems::Context<T>& context,
                                  systems::State<T>* state, const Body<T>& body,
                                  const SpatialVelocity<T>& V_WB) const {
    this->ValidateContext(context);
    this->ValidateCreatedForThisSystem(state);
    internal_tree().SetFreeBodySpatialVelocityOrThrow(body, V_WB, context,
                                                      state);
  }

  /// Sets the distribution used by SetRandomState() to populate the free
  /// body's x-y-z `position` with respect to World.
  /// @throws std::exception if `body` is not a free body in the model.
  /// @throws std::exception if called pre-finalize.
  void SetFreeBodyRandomPositionDistribution(
      const Body<T>& body, const Vector3<symbolic::Expression>& position) {
    this->mutable_tree().SetFreeBodyRandomPositionDistributionOrThrow(body,
                                                                      position);
  }

  /// Sets the distribution used by SetRandomState() to populate the free
  /// body's `rotation` with respect to World.
  /// @throws std::exception if `body` is not a free body in the model.
  /// @throws std::exception if called pre-finalize.
  void SetFreeBodyRandomRotationDistribution(
      const Body<T>& body,
      const Eigen::Quaternion<symbolic::Expression>& rotation) {
    this->mutable_tree().SetFreeBodyRandomRotationDistributionOrThrow(body,
                                                                      rotation);
  }

  /// Sets the distribution used by SetRandomState() to populate the free
  /// body's rotation with respect to World using uniformly random rotations.
  /// @throws std::exception if `body` is not a free body in the model.
  /// @throws std::exception if called pre-finalize.
  void SetFreeBodyRandomRotationDistributionToUniform(const Body<T>& body);

  /// Sets `context` to store the pose `X_WB` of a given `body` B in the world
  /// frame W.
  /// @param[in] context
  ///   The context to store the pose `X_WB` of `body_B`.
  /// @param[in] body_B
  ///   The body B corresponding to the pose `X_WB` to be stored in `context`.
  /// @retval X_WB
  ///   The pose of body frame B in the world frame W.
  /// @note In general setting the pose and/or velocity of a body in the model
  /// would involve a complex inverse kinematics problem. This method allows us
  /// to simplify this process when we know the body is free in space.
  /// @throws std::exception if `body` is not a free body in the model.
  /// @throws std::exception if called pre-finalize.
  void SetFreeBodyPoseInWorldFrame(systems::Context<T>* context,
                                   const Body<T>& body,
                                   const math::RigidTransform<T>& X_WB) const;

  /// Updates `context` to store the pose `X_FB` of a given `body` B in a frame
  /// F.
  /// Frame F must be anchored, meaning that it is either directly welded to the
  /// world frame W or, more generally, that there is a kinematic path between
  /// frame F and the world frame W that only includes weld joints.
  /// @throws std::exception if called pre-finalize.
  /// @throws std::exception if frame F is not anchored to the world.
  void SetFreeBodyPoseInAnchoredFrame(
      systems::Context<T>* context, const Frame<T>& frame_F,
      const Body<T>& body, const math::RigidTransform<T>& X_FB) const;

  /// If there exists a unique base body that belongs to the model given by
  /// `model_instance` and that unique base body is free
  /// (see HasUniqueBaseBody()), return that free body. Throw an exception
  /// otherwise.
  /// @throws std::exception if called pre-finalize.
  /// @throws std::exception if `model_instance` is not valid.
  /// @throws std::exception if HasUniqueFreeBaseBody(model_instance) == false.
  const Body<T>& GetUniqueFreeBaseBodyOrThrow(
      ModelInstanceIndex model_instance) const {
    DRAKE_MBP_THROW_IF_NOT_FINALIZED();
    return internal_tree().GetUniqueFreeBaseBodyOrThrowImpl(model_instance);
  }

  /// Return true if there exists a unique base body in the model given by
  /// `model_instance` and that unique base body is free.
  /// @throws std::exception if called pre-finalize.
  /// @throws std::exception if `model_instance` is not valid.
  bool HasUniqueFreeBaseBody(ModelInstanceIndex model_instance) const {
    DRAKE_MBP_THROW_IF_NOT_FINALIZED();
    return internal_tree().HasUniqueFreeBaseBodyImpl(model_instance);
  }

  /// @} <!-- Working with free bodies -->

  /// @anchor mbp_kinematic_and_dynamic_computations
  /// @name             Kinematic and dynamic computations
  /// These methods return kinematic results for the state supplied in the given
  /// @ref systems::Context "Context". Methods whose names being with `Eval`
  /// return a reference
  /// into the Context's cache, performing computation first only if the
  /// relevant state has changed. Methods beginning with `Calc` perform
  /// computation unconditionally and return a result without updating the
  /// cache.
  /// @{

  /// Evaluate the pose `X_WB` of a body B in the world frame W.
  /// @param[in] context
  ///   The context storing the state of the model.
  /// @param[in] body_B
  ///   The body B for which the pose is requested.
  /// @retval X_WB
  ///   The pose of body frame B in the world frame W.
  /// @throws std::exception if Finalize() was not called on `this` model or
  ///   if `body_B` does not belong to this model.
  const math::RigidTransform<T>& EvalBodyPoseInWorld(
      const systems::Context<T>& context, const Body<T>& body_B) const {
    this->ValidateContext(context);
    return internal_tree().EvalBodyPoseInWorld(context, body_B);
  }

  /// Evaluates V_WB, body B's spatial velocity in the world frame W.
  /// @param[in] context The context storing the state of the model.
  /// @param[in] body_B  The body B for which the spatial velocity is requested.
  /// @retval V_WB_W Body B's spatial velocity in the world frame W,
  ///   expressed in W (for point Bo, the body's origin).
  /// @throws std::exception if Finalize() was not called on `this` model or
  ///   if `body_B` does not belong to this model.
  const SpatialVelocity<T>& EvalBodySpatialVelocityInWorld(
      const systems::Context<T>& context, const Body<T>& body_B) const {
    this->ValidateContext(context);
    return internal_tree().EvalBodySpatialVelocityInWorld(context, body_B);
  }

  /// Evaluates A_WB, body B's spatial acceleration in the world frame W.
  /// @param[in] context The context storing the state of the model.
  /// @param[in] body_B  The body for which spatial acceleration is requested.
  /// @retval A_WB_W Body B's spatial acceleration in the world frame W,
  ///   expressed in W (for point Bo, the body's origin).
  /// @throws std::exception if Finalize() was not called on `this` model or
  ///   if `body_B` does not belong to this model.
  /// @note When cached values are out of sync with the state stored in context,
  /// this method performs an expensive forward dynamics computation, whereas
  /// once evaluated, successive calls to this method are inexpensive.
  const SpatialAcceleration<T>& EvalBodySpatialAccelerationInWorld(
      const systems::Context<T>& context, const Body<T>& body_B) const;

  /// Evaluates all point pairs of contact for a given state of the model stored
  /// in `context`.
  /// Each entry in the returned vector corresponds to a single point pair
  /// corresponding to two interpenetrating bodies A and B. The size of the
  /// returned vector corresponds to the total number of contact penetration
  /// pairs. If no geometry was registered, the output vector is empty.
  /// @see @ref mbp_geometry "Geometry" for geometry registration.
  /// @see PenetrationAsPointPair for further details on the returned data.
  /// @throws std::exception if called pre-finalize. See Finalize().
  const std::vector<geometry::PenetrationAsPointPair<T>>&
  EvalPointPairPenetrations(const systems::Context<T>& context) const {
    // TODO(jwnimmer-tri) This function is too large to be inline.
    // Move its definition to the cc file.
    DRAKE_MBP_THROW_IF_NOT_FINALIZED();
    this->ValidateContext(context);
    switch (contact_model_) {
      case ContactModel::kPoint:
        return this->get_cache_entry(cache_indexes_.point_pairs)
            .template Eval<std::vector<geometry::PenetrationAsPointPair<T>>>(
                context);
      case ContactModel::kHydroelasticWithFallback: {
        const auto& data =
            this->get_cache_entry(cache_indexes_.hydro_fallback)
                .template Eval<internal::HydroelasticFallbackCacheData<T>>(
                    context);
        return data.point_pairs;
      }
      default:
        throw std::logic_error(
            "Attempting to evaluate point pair contact for contact model that "
            "doesn't use it");
    }
  }

  /// Calculates the rigid transform (pose) `X_FG` relating frame F and frame G.
  /// @param[in] context
  ///    The state of the multibody system, which includes the system's
  ///    generalized positions q.  Note: `X_FG` is a function of q.
  /// @param[in] frame_F
  ///    The frame F designated in the rigid transform `X_FG`.
  /// @param[in] frame_G
  ///    The frame G designated in the rigid transform `X_FG`.
  /// @retval X_FG
  ///    The RigidTransform relating frame F and frame G.
  math::RigidTransform<T> CalcRelativeTransform(
      const systems::Context<T>& context, const Frame<T>& frame_F,
      const Frame<T>& frame_G) const {
    this->ValidateContext(context);
    return internal_tree().CalcRelativeTransform(context, frame_F, frame_G);
  }

  /// Calculates the rotation matrix `R_FG` relating frame F and frame G.
  /// @param[in] context
  ///    The state of the multibody system, which includes the system's
  ///    generalized positions q.  Note: `R_FG` is a function of q.
  /// @param[in] frame_F
  ///    The frame F designated in the rigid transform `R_FG`.
  /// @param[in] frame_G
  ///    The frame G designated in the rigid transform `R_FG`.
  /// @retval R_FG
  ///    The RigidTransform relating frame F and frame G.
  math::RotationMatrix<T> CalcRelativeRotationMatrix(
      const systems::Context<T>& context, const Frame<T>& frame_F,
      const Frame<T>& frame_G) const {
    this->ValidateContext(context);
    return internal_tree().CalcRelativeRotationMatrix(context, frame_F,
                                                      frame_G);
  }

  /// Given the positions `p_BQi` for a set of points `Qi` measured and
  /// expressed in a frame B, this method computes the positions `p_AQi(q)` of
  /// each point `Qi` in the set as measured and expressed in another frame A,
  /// as a function of the generalized positions q of the model.
  ///
  /// @param[in] context
  ///   The context containing the state of the model. It stores the
  ///   generalized positions q of the model.
  /// @param[in] frame_B
  ///   The frame B in which the positions `p_BQi` of a set of points `Qi` are
  ///   given.
  /// @param[in] p_BQi
  ///   The input positions of each point `Qi` in frame B. `p_BQi ∈ ℝ³ˣⁿᵖ` with
  ///   `np` the number of points in the set. Each column of `p_BQi` corresponds
  ///   to a vector in ℝ³ holding the position of one of the points in the set
  ///   as measured and expressed in frame B.
  /// @param[in] frame_A
  ///   The frame A in which it is desired to compute the positions `p_AQi` of
  ///   each point `Qi` in the set.
  /// @param[out] p_AQi
  ///   The output positions of each point `Qi` now computed as measured and
  ///   expressed in frame A. The output `p_AQi` **must** have the same size as
  ///   the input `p_BQi` or otherwise this method aborts. That is `p_AQi`
  ///   **must** be in `ℝ³ˣⁿᵖ`.
  ///
  /// @note Both `p_BQi` and `p_AQi` must have three rows. Otherwise this
  /// method will throw a std::exception. This method also throws
  /// a std::exception if `p_BQi` and `p_AQi` differ in the number
  /// of columns.
  void CalcPointsPositions(const systems::Context<T>& context,
                           const Frame<T>& frame_B,
                           const Eigen::Ref<const MatrixX<T>>& p_BQi,
                           const Frame<T>& frame_A,
                           EigenPtr<MatrixX<T>> p_AQi) const {
    this->ValidateContext(context);
    DRAKE_DEMAND(p_AQi != nullptr);
    return internal_tree().CalcPointsPositions(context, frame_B, p_BQi, frame_A,
                                               p_AQi);
  }

  /// Calculates the total mass of all bodies in this MultibodyPlant.
  /// @param[in] context Contains the state of the model.
  /// @retval The total mass of all bodies or 0 if there are none.
  /// @note The mass of the world_body() does not contribute to the total mass.
  T CalcTotalMass(const systems::Context<T>& context) const {
    this->ValidateContext(context);
    return internal_tree().CalcTotalMass(context);
  }

  /// Calculates the total mass of all bodies contained in model_instances.
  /// @param[in] context Contains the state of the model.
  /// @param[in] model_instances Vector of selected model instances. This method
  /// does not distinguish between welded, joint connected, or floating bodies.
  /// @retval The total mass of all bodies belonging to a model instance in
  ///   model_instances or 0 if model_instances is empty.
  /// @note The mass of the world_body() does not contribute to the total mass
  ///   and each body only contributes to the total mass once, even if the body
  ///   has repeated occurrence (instance) in model_instances.
  T CalcTotalMass(
      const systems::Context<T>& context,
      const std::vector<ModelInstanceIndex>& model_instances) const {
    this->ValidateContext(context);
    return internal_tree().CalcTotalMass(context, model_instances);
  }

  /// Calculates the position vector from the world origin Wo to the center of
  /// mass of all bodies in this MultibodyPlant, expressed in the world frame W.
  /// @param[in] context Contains the state of the model.
  /// @retval p_WoScm_W position vector from Wo to Scm expressed in world frame
  /// W, where Scm is the center of mass of the system S stored by `this` plant.
  /// @throws std::exception if `this` has no body except world_body().
  /// @throws std::exception if mₛ ≤ 0 (where mₛ is the mass of system S).
  /// @note The world_body() is ignored.  p_WoScm_W = ∑ (mᵢ pᵢ) / mₛ, where
  /// mₛ = ∑ mᵢ, mᵢ is the mass of the iᵗʰ body, and pᵢ is Bcm's position vector
  /// from Wo expressed in frame W (Bcm is the center of mass of the iᵗʰ body).
  Vector3<T> CalcCenterOfMassPositionInWorld(
      const systems::Context<T>& context) const {
    this->ValidateContext(context);
    return internal_tree().CalcCenterOfMassPositionInWorld(context);
  }

  /// Calculates the position vector from the world origin Wo to the center of
  /// mass of all non-world bodies contained in model_instances, expressed in
  /// the world frame W.
  /// @param[in] context Contains the state of the model.
  /// @param[in] model_instances Vector of selected model instances.  If a model
  /// instance is repeated in the vector (unusual), it is only counted once.
  /// @retval p_WoScm_W position vector from world origin Wo to Scm expressed in
  /// the world frame W, where Scm is the center of mass of the system S of
  /// non-world bodies contained in model_instances.
  /// @throws std::exception if model_instances is empty or only has world body.
  /// @throws std::exception if mₛ ≤ 0 (where mₛ is the mass of system S).
  /// @note The world_body() is ignored.  p_WoScm_W = ∑ (mᵢ pᵢ) / mₛ, where
  /// mₛ = ∑ mᵢ, mᵢ is the mass of the iᵗʰ body contained in model_instances,
  /// and pᵢ is Bcm's position vector from Wo expressed in frame W
  /// (Bcm is the center of mass of the iᵗʰ body).
  Vector3<T> CalcCenterOfMassPositionInWorld(
      const systems::Context<T>& context,
      const std::vector<ModelInstanceIndex>& model_instances) const {
    this->ValidateContext(context);
    return internal_tree().CalcCenterOfMassPositionInWorld(context,
                                                           model_instances);
  }

  /// Returns M_SFo_F, the spatial inertia of a set S of bodies about point Fo
  /// (the origin of a frame F), expressed in frame F. You may regard M_SFo_F as
  /// measuring spatial inertia as if the set S of bodies were welded into a
  /// single composite body at the configuration specified in the `context`.
  /// @param[in] context Contains the configuration of the set S of bodies.
  /// @param[in] frame_F specifies the about-point Fo (frame_F's origin) and
  ///  the expressed-in frame for the returned spatial inertia.
  /// @param[in] body_indexes Array of selected bodies.  This method does not
  ///  distinguish between welded bodies, joint-connected bodies, etc.
  /// @throws std::exception if body_indexes contains an invalid BodyIndex or
  ///  if there is a repeated BodyIndex.
  /// @note The mass and inertia of the world_body() does not contribute to the
  ///  the returned spatial inertia.
  SpatialInertia<T> CalcSpatialInertia(
      const systems::Context<T>& context, const Frame<T>& frame_F,
      const std::vector<BodyIndex>& body_indexes) const {
    this->ValidateContext(context);
    return internal_tree().CalcSpatialInertia(context, frame_F, body_indexes);
  }

  /// Calculates system center of mass translational velocity in world frame W.
  /// @param[in] context The context contains the state of the model.
  /// @retval v_WScm_W Scm's translational velocity in frame W, expressed in W,
  /// where Scm is the center of mass of the system S stored by `this` plant.
  /// @throws std::exception if `this` has no body except world_body().
  /// @throws std::exception if mₛ ≤ 0 (where mₛ is the mass of system S).
  /// @note The world_body() is ignored.  v_WScm_W = ∑ (mᵢ vᵢ) / mₛ, where
  /// mₛ = ∑ mᵢ, mᵢ is the mass of the iᵗʰ body, and vᵢ is Bcm's velocity in
  /// world W (Bcm is the center of mass of the iᵗʰ body).
  Vector3<T> CalcCenterOfMassTranslationalVelocityInWorld(
      const systems::Context<T>& context) const {
    return internal_tree().CalcCenterOfMassTranslationalVelocityInWorld(
        context);
  }

  /// Calculates system center of mass translational velocity in world frame W.
  /// @param[in] context The context contains the state of the model.
  /// @param[in] model_instances Vector of selected model instances.  If a model
  /// instance is repeated in the vector (unusual), it is only counted once.
  /// @retval v_WScm_W Scm's translational velocity in frame W, expressed in W,
  /// where Scm is the center of mass of the system S of non-world bodies
  /// contained in model_instances.
  /// @throws std::exception if model_instances is empty or only has world body.
  /// @throws std::exception if mₛ ≤ 0 (where mₛ is the mass of system S).
  /// @note The world_body() is ignored.  v_WScm_W = ∑ (mᵢ vᵢ) / mₛ, where
  /// mₛ = ∑ mᵢ, mᵢ is the mass of the iᵗʰ body contained in model_instances,
  /// and vᵢ is Bcm's velocity in world W expressed in frame W
  /// (Bcm is the center of mass of the iᵗʰ body).
  Vector3<T> CalcCenterOfMassTranslationalVelocityInWorld(
      const systems::Context<T>& context,
      const std::vector<ModelInstanceIndex>& model_instances) const {
    return internal_tree().CalcCenterOfMassTranslationalVelocityInWorld(
        context, model_instances);
  }

  /// This method returns the spatial momentum of `this` MultibodyPlant in the
  /// world frame W, about a designated point P, expressed in the world frame W.
  /// @param[in] context Contains the state of the model.
  /// @param[in] p_WoP_W Position from Wo (origin of the world frame W) to an
  ///            arbitrary point P, expressed in the world frame W.
  /// @retval L_WSP_W, spatial momentum of the system S represented by `this`
  ///   plant, measured in the world frame W, about point P, expressed in W.
  /// @note To calculate the spatial momentum of this system S in W about Scm
  /// (the system's center of mass), use something like: <pre>
  ///   MultibodyPlant<T> plant;
  ///   // ... code to load a model ....
  ///   const Vector3<T> p_WoScm_W =
  ///     plant.CalcCenterOfMassPositionInWorld(context);
  ///   const SpatialMomentum<T> L_WScm_W =
  ///     plant.CalcSpatialMomentumInWorldAboutPoint(context, p_WoScm_W);
  /// </pre>
  SpatialMomentum<T> CalcSpatialMomentumInWorldAboutPoint(
      const systems::Context<T>& context, const Vector3<T>& p_WoP_W) const {
    this->ValidateContext(context);
    return internal_tree().CalcSpatialMomentumInWorldAboutPoint(context,
                                                                p_WoP_W);
  }

  /// This method returns the spatial momentum of a set of model instances in
  /// the world frame W, about a designated point P, expressed in frame W.
  /// @param[in] context Contains the state of the model.
  /// @param[in] model_instances Set of selected model instances.
  /// @param[in] p_WoP_W Position from Wo (origin of the world frame W) to an
  ///            arbitrary point P, expressed in the world frame W.
  /// @retval L_WSP_W, spatial momentum of the system S represented by the
  /// model_instances, measured in world frame W, about point P, expressed in W.
  /// @note To calculate the spatial momentum of this system S in W about Scm
  /// (the system's center of mass), use something like: <pre>
  ///   MultibodyPlant<T> plant;
  ///   // ... code to create a set of selected model instances, e.g., ...
  ///   const ModelInstanceIndex gripper_model_instance =
  ///     plant.GetModelInstanceByName("gripper");
  ///   const ModelInstanceIndex robot_model_instance =
  ///     plant.GetBodyByName("end_effector").model_instance();
  ///   const std::vector<ModelInstanceIndex> model_instances{
  ///     gripper_model_instance, robot_model_instance};
  ///   const Vector3<T> p_WoScm_W =
  ///     plant.CalcCenterOfMassPositionInWorld(context, model_instances);
  ///   SpatialMomentum<T> L_WScm_W =
  ///     plant.CalcSpatialMomentumInWorldAboutPoint(context, model_instances,
  ///                                                p_WoScm_W);
  /// </pre>
  /// @throws std::exception if model_instances contains an invalid
  ///         ModelInstanceIndex.
  SpatialMomentum<T> CalcSpatialMomentumInWorldAboutPoint(
      const systems::Context<T>& context,
      const std::vector<ModelInstanceIndex>& model_instances,
      const Vector3<T>& p_WoP_W) const {
    this->ValidateContext(context);
    return internal_tree().CalcSpatialMomentumInWorldAboutPoint(
        context, model_instances, p_WoP_W);
  }

  /// Given the state of this model in `context` and a known vector
  /// of generalized accelerations `known_vdot`, this method computes the
  /// spatial acceleration `A_WB` for each body as measured and expressed in the
  /// world frame W.
  ///
  /// @param[in] context
  ///   The context containing the state of this model.
  /// @param[in] known_vdot
  ///   A vector with the generalized accelerations for the full model.
  /// @param[out] A_WB_array
  ///   A pointer to a valid, non nullptr, vector of spatial accelerations
  ///   containing the spatial acceleration `A_WB` for each body. It must be of
  ///   size equal to the number of bodies in the model. On output,
  ///   entries will be ordered by BodyIndex.
  /// @throws std::exception if A_WB_array is not of size `num_bodies()`.
  void CalcSpatialAccelerationsFromVdot(
      const systems::Context<T>& context, const VectorX<T>& known_vdot,
      std::vector<SpatialAcceleration<T>>* A_WB_array) const;

  /// Given the state of this model in `context` and a known vector
  /// of generalized accelerations `vdot`, this method computes the
  /// set of generalized forces `tau` that would need to be applied in order to
  /// attain the specified generalized accelerations.
  /// Mathematically, this method computes: <pre>
  ///   tau = M(q)v̇ + C(q, v)v - tau_app - ∑ J_WBᵀ(q) Fapp_Bo_W
  /// </pre>
  /// where `M(q)` is the model's mass matrix (including rigid body mass
  /// properties and @ref reflected_inertia "reflected inertias"), `C(q, v)v` is
  /// the bias term for Coriolis and gyroscopic effects and `tau_app` consists
  /// of a vector applied generalized forces. The last term is a summation over
  /// all bodies in the model where `Fapp_Bo_W` is an applied spatial force on
  /// body B at `Bo` which gets projected into the space of generalized forces
  /// with the transpose of `Jv_V_WB(q)` (where `Jv_V_WB` is B's spatial
  /// velocity Jacobian in W with respect to generalized velocities v).
  /// Note: B's spatial velocity in W can be written as `V_WB = Jv_V_WB * v`.
  ///
  /// This method does not compute explicit expressions for the mass matrix nor
  /// for the bias term, which would be of at least `O(n²)` complexity, but it
  /// implements an `O(n)` Newton-Euler recursive algorithm, where n is the
  /// number of bodies in the model. The explicit formation of the
  /// mass matrix `M(q)` would require the calculation of `O(n²)` entries while
  /// explicitly forming the product `C(q, v) * v` could require up to `O(n³)`
  /// operations (see [Featherstone 1987, §4]), depending on the implementation.
  /// The recursive Newton-Euler algorithm is the most efficient currently known
  /// general method for solving inverse dynamics [Featherstone 2008].
  ///
  /// @param[in] context
  ///   The context containing the state of the model.
  /// @param[in] known_vdot
  ///   A vector with the known generalized accelerations `vdot` for the full
  ///   model. Use the provided Joint APIs in order to access entries into this
  ///   array.
  /// @param[in] external_forces
  ///   A set of forces to be applied to the system either as body spatial
  ///   forces `Fapp_Bo_W` or generalized forces `tau_app`, see MultibodyForces
  ///   for details.
  ///
  /// @returns the vector of generalized forces that would need to be applied to
  /// the mechanical system in order to achieve the desired acceleration given
  /// by `known_vdot`.
  VectorX<T> CalcInverseDynamics(
      const systems::Context<T>& context, const VectorX<T>& known_vdot,
      const MultibodyForces<T>& external_forces) const {
    this->ValidateContext(context);
    return internal_tree().CalcInverseDynamics(context, known_vdot,
                                               external_forces);
  }

#ifdef DRAKE_DOXYGEN_CXX
  // MultibodyPlant uses the NVI implementation of
  // CalcImplicitTimeDerivativesResidual from
  // MultibodyTreeSystem::DoCalcImplicitTimeDerivativesResidual.  We provide the
  // public facing documentation for it here.

  /// MultibodyPlant implements the
  /// systems::System::CalcImplicitTimeDerivativesResidual method when the plant
  /// is modeled as a continuous-time system, returning one residual for each
  /// multibody state.  In particular, the first num_positions() residuals are
  /// given by <pre>
  ///   q̇_proposed - N(q)⋅v
  /// </pre>
  /// and the final num_velocities() residuals are given by <pre>
  ///   CalcInverseDynamics(context, v_proposed)
  /// </pre>
  /// including all actuator and applied forces.
  /// @see systems::System::CalcImplicitTimeDerivativesResidual for more
  /// details.
  void CalcImplicitTimeDerivativesResidual(
      const systems::Context<T>& context,
      const systems::ContinuousState<T>& proposed_derivatives,
      EigenPtr<VectorX<T>> residual) const;
#endif

  /// Computes the combined force contribution of ForceElement objects in the
  /// model. A ForceElement can apply forces as a spatial force per body or as
  /// generalized forces, depending on the ForceElement model.
  /// ForceElement contributions are a function of the state and time only.
  /// The output from this method can immediately be used as input to
  /// CalcInverseDynamics() to include the effect of applied forces by force
  /// elements.
  ///
  /// @param[in] context
  ///   The context containing the state of this model.
  /// @param[out] forces
  ///   A pointer to a valid, non nullptr, multibody forces object. On output
  ///   `forces` will store the forces exerted by all the ForceElement
  ///   objects in the model.
  /// @throws std::exception if `forces` is null or not compatible with this
  ///   model, per MultibodyForces::CheckInvariants().
  void CalcForceElementsContribution(const systems::Context<T>& context,
                                     MultibodyForces<T>* forces) const;

  /// Computes the generalized forces `tau_g(q)` due to gravity as a function
  /// of the generalized positions `q` stored in the input `context`.
  /// The vector of generalized forces due to gravity `tau_g(q)` is defined such
  /// that it appears on the right hand side of the equations of motion together
  /// with any other generalized forces, like so:
  /// <pre>
  ///   Mv̇ + C(q, v)v = tau_g(q) + tau_app
  /// </pre>
  /// where `tau_app` includes any other generalized forces applied on the
  /// system.
  ///
  /// @param[in] context
  ///   The context storing the state of the model.
  /// @returns tau_g
  ///   A vector containing the generalized forces due to gravity.
  ///   The generalized forces are consistent with the vector of
  ///   generalized velocities `v` for `this` so that
  ///   the inner product `v⋅tau_g` corresponds to the power applied by the
  ///   gravity forces on the mechanical system. That is, `v⋅tau_g > 0`
  ///   corresponds to potential energy going into the system, as either
  ///   mechanical kinetic energy, some other potential energy, or heat, and
  ///   therefore to a decrease of the gravitational potential energy.
  VectorX<T> CalcGravityGeneralizedForces(
      const systems::Context<T>& context) const {
    this->ValidateContext(context);
    return internal_tree().CalcGravityGeneralizedForces(context);
  }

  /// Computes the generalized forces result of a set of MultibodyForces applied
  /// to this model.
  ///
  /// MultibodyForces stores applied forces as both generalized forces τ and
  /// spatial forces F on each body, refer to documentation in MultibodyForces
  /// for details. Users of MultibodyForces will use
  /// MultibodyForces::mutable_generalized_forces() to mutate the stored
  /// generalized forces directly and will use Body::AddInForceInWorld() to
  /// append spatial forces.
  ///
  /// For a given set of forces stored as MultibodyForces, this method will
  /// compute the total generalized forces on this model. More precisely, if
  /// J_WBo is the Jacobian (with respect to velocities) for this model,
  /// including all bodies, then this method computes: <pre>
  ///   τᵣₑₛᵤₗₜ = τ + J_WBo⋅F
  /// </pre>
  ///
  /// @param[in] context Context that stores the state of the model.
  /// @param[in] forces Set of multibody forces, including both generalized
  /// forces and per-body spatial forces.
  /// @param[out] generalized_forces The total generalized forces on the model
  /// that would result from applying `forces`. In other words, `forces` can be
  /// replaced by the equivalent `generalized_forces`. On output,
  /// `generalized_forces` is resized to num_velocities().
  ///
  /// @throws std::exception if `forces` is null or not compatible with this
  /// model.
  /// @throws std::exception if `generalized_forces` is not a valid non-null
  /// pointer.
  void CalcGeneralizedForces(const systems::Context<T>& context,
                             const MultibodyForces<T>& forces,
                             VectorX<T>* generalized_forces) const;

  /// Returns true iff the generalized velocity v is exactly the time
  /// derivative q̇ of the generalized coordinates q. In this case
  /// MapQDotToVelocity() and MapVelocityToQDot() implement the identity map.
  /// This method is, in the worst case, O(n), where n is the number of joints.
  bool IsVelocityEqualToQDot() const {
    // TODO(sherm1): Consider caching this value.
    return internal_tree().IsVelocityEqualToQDot();
  }

  // Preserve access to base overload from this class.
  using systems::System<T>::MapVelocityToQDot;

  /// Transforms generalized velocities v to time derivatives `qdot` of the
  /// generalized positions vector `q` (stored in `context`). `v` and `qdot`
  /// are related linearly by `q̇ = N(q)⋅v`.
  /// Using the configuration `q` stored in the given `context` this method
  /// calculates `q̇ = N(q)⋅v`.
  ///
  /// @param[in] context
  ///   The context containing the state of the model.
  /// @param[in] v
  ///   A vector of generalized velocities for this model.
  ///   This method aborts if v is not of size num_velocities().
  /// @param[out] qdot
  ///   A valid (non-null) pointer to a vector in `ℝⁿ` with n being the number
  ///   of generalized positions in this model,
  ///   given by `num_positions()`. This method aborts if `qdot` is nullptr
  ///   or if it is not of size num_positions().
  ///
  /// @see MapQDotToVelocity()
  /// @see Mobilizer::MapVelocityToQDot()
  void MapVelocityToQDot(const systems::Context<T>& context,
                         const Eigen::Ref<const VectorX<T>>& v,
                         EigenPtr<VectorX<T>> qdot) const {
    this->ValidateContext(context);
    DRAKE_DEMAND(qdot != nullptr);
    return internal_tree().MapVelocityToQDot(context, v, qdot);
  }

  // Preserve access to base overload from this class.
  using systems::System<T>::MapQDotToVelocity;

  /// Transforms the time derivative `qdot` of the generalized positions vector
  /// `q` (stored in `context`) to generalized velocities `v`. `v` and `q̇`
  /// are related linearly by `q̇ = N(q)⋅v`. Although `N(q)` is not
  /// necessarily square, its left pseudo-inverse `N⁺(q)` can be used to
  /// invert that relationship without residual error, provided that `qdot` is
  /// in the range space of `N(q)` (that is, if it *could* have been produced as
  /// `q̇ = N(q)⋅v` for some `v`).
  /// Using the configuration `q` stored in the given `context` this method
  /// calculates `v = N⁺(q)⋅q̇`.
  ///
  /// @param[in] context
  ///   The context containing the state of the model.
  /// @param[in] qdot
  ///   A vector containing the time derivatives of the generalized positions.
  ///   This method aborts if `qdot` is not of size num_positions().
  /// @param[out] v
  ///   A valid (non-null) pointer to a vector in `ℛⁿ` with n the number of
  ///   generalized velocities. This method aborts if v is nullptr or if it
  ///   is not of size num_velocities().
  ///
  /// @see MapVelocityToQDot()
  /// @see Mobilizer::MapQDotToVelocity()
  void MapQDotToVelocity(const systems::Context<T>& context,
                         const Eigen::Ref<const VectorX<T>>& qdot,
                         EigenPtr<VectorX<T>> v) const {
    this->ValidateContext(context);
    DRAKE_DEMAND(v != nullptr);
    internal_tree().MapQDotToVelocity(context, qdot, v);
  }

  /// Returns the matrix `N(q)`, which maps `q̇ = N(q)⋅v`, as described in
  /// MapVelocityToQDot(). Prefer calling MapVelocityToQDot() directly; this
  /// entry point is provided to support callers that require the explicit
  /// linear form (once q is given) of the relationship. Do not take the
  /// (pseudo-)inverse of `N(q)`; call MakeQDotToVelocityMap instead. This
  /// method is, in the worst case, O(n), where n is the number of joints.
  ///
  /// @param[in] context
  ///   The context containing the state of the model.
  ///
  /// @see MapVelocityToQDot()
  Eigen::SparseMatrix<T> MakeVelocityToQDotMap(
      const systems::Context<T>& context) const {
    this->ValidateContext(context);
    return internal_tree().MakeVelocityToQDotMap(context);
  }

  /// Returns the matrix `N⁺(q)`, which maps `v = N⁺(q)⋅q̇`, as described in
  /// MapQDotToVelocity(). Prefer calling MapQDotToVelocity() directly; this
  /// entry point is provided to support callers that require the explicit
  /// linear form (once q is given) of the relationship. This method is, in the
  /// worst case, O(n), where n is the number of joints.
  ///
  /// @param[in] context
  ///   The context containing the state of the model.
  ///
  /// @see MapVelocityToQDot()
  Eigen::SparseMatrix<T> MakeQDotToVelocityMap(
      const systems::Context<T>& context) const {
    this->ValidateContext(context);
    return internal_tree().MakeQDotToVelocityMap(context);
  }
  /// @} <!-- Kinematic and dynamic computations -->

  /// @anchor mbp_system_matrix_computations
  /// @name                System matrix computations
  /// Methods in this section compute and return various matrices that
  /// appear in the system equations of motion. For better performance, prefer
  /// to use direct computations where available rather than work with explicit
  /// matrices. See
  /// @ref mbp_kinematic_and_dynamic_computations
  /// "Kinematic and dynamics computations" for available computations. For
  /// example, you can obtain the mass matrix, Coriolis, centripetal, and
  /// gyroscopic "bias" terms, and a variety of Jacobian and actuation matrices.
  /// @{

  /// Computes the mass matrix `M(q)` of the model using a slow method (inverse
  /// dynamics). The generalized positions q are taken from the given `context`.
  /// M includes the mass properties of rigid bodies and @ref reflected_inertia
  /// "reflected inertias" as provided with JointActuator specifications.
  ///
  /// Use CalcMassMatrix() for a faster implementation using the Composite %Body
  /// Algorithm.
  ///
  /// @param[in] context
  ///   The Context containing the state of the model from which generalized
  ///   coordinates q are extracted.
  /// @param[out] M
  ///   A pointer to a square matrix in `ℛⁿˣⁿ` with n the number of generalized
  ///   velocities (num_velocities()) of the model. Although symmetric, the
  ///   matrix is filled in completely on return.
  ///
  /// @pre M is non-null and has the right size.
  ///
  /// The algorithm used to build `M(q)` consists in computing one column of
  /// `M(q)` at a time using inverse dynamics. The result from inverse dynamics,
  /// with no applied forces, is the vector of generalized forces: <pre>
  ///   tau = M(q)v̇ + C(q, v)v
  /// </pre>
  /// where q and v are the generalized positions and velocities, respectively.
  /// When `v = 0` the Coriolis and gyroscopic forces term `C(q, v)v` is zero.
  /// Therefore the `i-th` column of `M(q)` can be obtained performing inverse
  /// dynamics with an acceleration vector `v̇ = eᵢ`, with `eᵢ` the standard
  /// (or natural) basis of `ℛⁿ` with n the number of generalized velocities.
  /// We write this as: <pre>
  ///   M.ᵢ(q) = M(q) * e_i
  /// </pre>
  /// where `M.ᵢ(q)` (notice the dot for the rows index) denotes the `i-th`
  /// column in M(q).
  ///
  /// @warning This is an O(n²) algorithm. Avoid the explicit computation of the
  /// mass matrix whenever possible.
  /// @see CalcMassMatrix(), CalcInverseDynamics()
  void CalcMassMatrixViaInverseDynamics(const systems::Context<T>& context,
                                        EigenPtr<MatrixX<T>> M) const {
    this->ValidateContext(context);
    DRAKE_DEMAND(M != nullptr);
    internal_tree().CalcMassMatrixViaInverseDynamics(context, M);
  }

  /// Efficiently computes the mass matrix `M(q)` of the model. The generalized
  /// positions q are taken from the given `context`. M includes the mass
  /// properties of rigid bodies and @ref reflected_inertia "reflected inertias"
  /// as provided with JointActuator specifications.
  ///
  /// This method employs the Composite %Body Algorithm, which we believe to be
  /// the fastest O(n²) algorithm to compute the mass matrix of a multibody
  /// system.
  ///
  /// @param[in] context
  ///   The Context containing the state of the model from which generalized
  ///   coordinates q are extracted.
  /// @param[out] M
  ///   A pointer to a square matrix in `ℛⁿˣⁿ` with n the number of generalized
  ///   velocities (num_velocities()) of the model. Although symmetric, the
  ///   matrix is filled in completely on return.
  ///
  /// @pre M is non-null and has the right size.
  ///
  /// @warning This is an O(n²) algorithm. Avoid the explicit computation of the
  /// mass matrix whenever possible.
  /// @see CalcMassMatrixViaInverseDynamics() (slower)
  void CalcMassMatrix(const systems::Context<T>& context,
                      EigenPtr<MatrixX<T>> M) const {
    this->ValidateContext(context);
    DRAKE_DEMAND(M != nullptr);
    internal_tree().CalcMassMatrix(context, M);
  }

  /// Computes the bias term `C(q, v)v` containing Coriolis, centripetal, and
  /// gyroscopic effects in the multibody equations of motion: <pre>
  ///   M(q) v̇ + C(q, v) v = tau_app + ∑ (Jv_V_WBᵀ(q) ⋅ Fapp_Bo_W)
  /// </pre>
  /// where `M(q)` is the multibody model's mass matrix (including rigid body
  /// mass properties and @ref reflected_inertia "reflected inertias") and
  /// `tau_app` is a vector of applied generalized forces. The last term is a
  /// summation over all bodies of the dot-product of `Fapp_Bo_W` (applied
  /// spatial force on body B at Bo) with `Jv_V_WB(q)` (B's spatial Jacobian in
  /// world W with respect to generalized velocities v).
  /// Note: B's spatial velocity in W can be written `V_WB = Jv_V_WB * v`.
  ///
  /// @param[in] context
  ///   The context containing the state of the model. It stores the
  ///   generalized positions q and the generalized velocities v.
  /// @param[out] Cv
  ///   On output, `Cv` will contain the product `C(q, v)v`. It must be a valid
  ///   (non-null) pointer to a column vector in `ℛⁿ` with n the number of
  ///   generalized velocities (num_velocities()) of the model.
  ///   This method aborts if Cv is nullptr or if it does not have the
  ///   proper size.
  void CalcBiasTerm(const systems::Context<T>& context,
                    EigenPtr<VectorX<T>> Cv) const {
    this->ValidateContext(context);
    DRAKE_DEMAND(Cv != nullptr);
    internal_tree().CalcBiasTerm(context, Cv);
  }

  /// For each point Bi affixed/welded to a frame B, calculates a𝑠Bias_ABi, Bi's
  /// translational acceleration bias in frame A with respect to "speeds" 𝑠,
  /// where 𝑠 is either q̇ (time-derivatives of generalized positions) or v
  /// (generalized velocities).  a𝑠Bias_ABi is the term in a_ABi (Bi's
  /// translational acceleration in A) that does not include 𝑠̇, i.e.,
  /// a𝑠Bias_ABi is Bi's translational acceleration in A when 𝑠̇ = 0. <pre>
  ///   a_ABi =  J𝑠_v_ABi ⋅ 𝑠̇  +  J̇𝑠_v_ABi ⋅ 𝑠  (𝑠 = q̇ or 𝑠 = v), hence
  ///   a𝑠Bias_ABi = J̇𝑠_v_ABi ⋅ 𝑠
  /// </pre>
  /// where J𝑠_v_ABi is Bi's translational velocity Jacobian in frame A for s
  /// (see CalcJacobianTranslationalVelocity() for details on J𝑠_v_ABi).
  /// @param[in] context The state of the multibody system.
  /// @param[in] with_respect_to Enum equal to JacobianWrtVariable::kQDot or
  /// JacobianWrtVariable::kV, indicating whether the translational
  /// acceleration bias is with respect to 𝑠 = q̇ or 𝑠 = v.
  /// @param[in] frame_B The frame on which points Bi are affixed/welded.
  /// @param[in] p_BoBi_B A position vector or list of p position vectors from
  /// Bo (frame_B's origin) to points Bi (regarded as affixed to B), where each
  /// position vector is expressed in frame_B.  Each column in the `3 x p`
  /// matrix p_BoBi_B corresponds to a position vector.
  /// @param[in] frame_A The frame that measures a𝑠Bias_ABi.
  /// Currently, an exception is thrown if frame_A is not the World frame.
  /// @param[in] frame_E The frame in which a𝑠Bias_ABi is expressed on output.
  /// @returns a𝑠Bias_ABi_E Point Bi's translational acceleration bias in
  /// frame A with respect to speeds 𝑠 (𝑠 = q̇ or 𝑠 = v), expressed in frame E.
  /// a𝑠Bias_ABi_E is a `3 x p` matrix, where p is the number of points Bi.
  /// @note Shown below, a𝑠Bias_ABi_E = J̇𝑠_v_ABp ⋅ 𝑠  is quadratic in 𝑠.<pre>
  ///  v_ABi =  J𝑠_v_ABi ⋅ 𝑠        which upon vector differentiation in A gives
  ///  a_ABi =  J𝑠_v_ABi ⋅ 𝑠̇ + J̇𝑠_v_ABi ⋅ 𝑠     Since J̇𝑠_v_ABi is linear in 𝑠,
  ///  a𝑠Bias_ABi = J̇𝑠_v_ABi ⋅ 𝑠                             is quadratic in 𝑠.
  /// </pre>
  /// @see CalcJacobianTranslationalVelocity() to compute J𝑠_v_ABi, point Bi's
  /// translational velocity Jacobian in frame A with respect to 𝑠.
  /// @pre p_BoBi_B must have 3 rows.
  /// @throws std::exception if with_respect_to is not JacobianWrtVariable::kV
  /// @throws std::exception if frame_A is not the world frame.
  Matrix3X<T> CalcBiasTranslationalAcceleration(
      const systems::Context<T>& context, JacobianWrtVariable with_respect_to,
      const Frame<T>& frame_B, const Eigen::Ref<const Matrix3X<T>>& p_BoBi_B,
      const Frame<T>& frame_A, const Frame<T>& frame_E) const {
    // TODO(Mitiguy) Allow with_respect_to to be JacobianWrtVariable::kQDot.
    this->ValidateContext(context);
    return internal_tree().CalcBiasTranslationalAcceleration(
        context, with_respect_to, frame_B, p_BoBi_B, frame_A, frame_E);
  }

  /// For one point Bp affixed/welded to a frame B, calculates A𝑠Bias_ABp, Bp's
  /// spatial acceleration bias in frame A with respect to "speeds" 𝑠,
  /// where 𝑠 is either q̇ (time-derivatives of generalized positions) or v
  /// (generalized velocities).  A𝑠Bias_ABp is the term in A_ABp (Bp's
  /// spatial acceleration in A) that does not include 𝑠̇, i.e.,
  /// A𝑠Bias_ABp is Bi's translational acceleration in A when 𝑠̇ = 0. <pre>
  ///   A_ABp =  J𝑠_V_ABp ⋅ 𝑠̇  +  J̇𝑠_V_ABp ⋅ 𝑠   (𝑠 = q̇ or 𝑠 = v), hence
  ///   A𝑠Bias_ABp = J̇𝑠_V_ABp ⋅ 𝑠
  /// </pre>
  /// where J𝑠_V_ABp is Bp's spatial velocity Jacobian in frame A for speeds s
  /// (see CalcJacobianSpatialVelocity() for details on J𝑠_V_ABp).
  /// @param[in] context The state of the multibody system.
  /// @param[in] with_respect_to Enum equal to JacobianWrtVariable::kQDot or
  /// JacobianWrtVariable::kV, indicating whether the spatial accceleration bias
  /// is with respect to 𝑠 = q̇ or 𝑠 = v.
  /// @param[in] frame_B The frame on which point Bp is affixed/welded.
  /// @param[in] p_BoBp_B Position vector from Bo (frame_B's origin) to point Bp
  /// (regarded as affixed/welded to B), expressed in frame_B.
  /// @param[in] frame_A The frame that measures A𝑠Bias_ABp.
  /// Currently, an exception is thrown if frame_A is not the World frame.
  /// @param[in] frame_E The frame in which A𝑠Bias_ABp is expressed on output.
  /// @returns A𝑠Bias_ABp_E Point Bp's spatial acceleration bias in frame A
  /// with respect to speeds 𝑠 (𝑠 = q̇ or 𝑠 = v), expressed in frame E.
  /// @note Shown below, A𝑠Bias_ABp_E = J̇𝑠_V_ABp ⋅ 𝑠  is quadratic in 𝑠. <pre>
  ///  V_ABp =  J𝑠_V_ABp ⋅ 𝑠        which upon vector differentiation in A gives
  ///  A_ABp =  J𝑠_V_ABp ⋅ 𝑠̇  +  J̇𝑠_V_ABp ⋅ 𝑠   Since J̇𝑠_V_ABp is linear in 𝑠,
  ///  A𝑠Bias_ABp = J̇𝑠_V_ABp ⋅ 𝑠                             is quadratic in 𝑠.
  /// </pre>
  /// @see CalcJacobianSpatialVelocity() to compute J𝑠_V_ABp, point Bp's
  /// translational velocity Jacobian in frame A with respect to 𝑠.
  /// @throws std::exception if with_respect_to is not JacobianWrtVariable::kV
  /// @throws std::exception if frame_A is not the world frame.
  SpatialAcceleration<T> CalcBiasSpatialAcceleration(
      const systems::Context<T>& context, JacobianWrtVariable with_respect_to,
      const Frame<T>& frame_B, const Eigen::Ref<const Vector3<T>>& p_BoBp_B,
      const Frame<T>& frame_A, const Frame<T>& frame_E) const {
    // TODO(Mitiguy) Allow with_respect_to to be JacobianWrtVariable::kQDot.
    this->ValidateContext(context);
    return internal_tree().CalcBiasSpatialAcceleration(
        context, with_respect_to, frame_B, p_BoBp_B, frame_A, frame_E);
  }

  /// For one point Bp fixed/welded to a frame B, calculates J𝑠_V_ABp, Bp's
  /// spatial velocity Jacobian in frame A with respect to "speeds" 𝑠.
  /// <pre>
  ///      J𝑠_V_ABp ≜ [ ∂(V_ABp)/∂𝑠₁,  ...  ∂(V_ABp)/∂𝑠ₙ ]    (n is j or k)
  ///      V_ABp = J𝑠_V_ABp ⋅ 𝑠          V_ABp is linear in 𝑠 ≜ [𝑠₁ ... 𝑠ₙ]ᵀ
  /// </pre>
  /// `V_ABp` is Bp's spatial velocity in frame A and "speeds" 𝑠 is either
  /// q̇ ≜ [q̇₁ ... q̇ⱼ]ᵀ (time-derivatives of j generalized positions) or
  /// v ≜ [v₁ ... vₖ]ᵀ (k generalized velocities).
  ///
  /// @param[in] context The state of the multibody system.
  /// @param[in] with_respect_to Enum equal to JacobianWrtVariable::kQDot or
  /// JacobianWrtVariable::kV, indicating whether the Jacobian `J𝑠_V_ABp` is
  /// partial derivatives with respect to 𝑠 = q̇ (time-derivatives of generalized
  /// positions) or with respect to 𝑠 = v (generalized velocities).
  /// @param[in] frame_B The frame on which point Bp is fixed/welded.
  /// @param[in] p_BoBp_B A position vector from Bo (frame_B's origin) to point
  /// Bp (regarded as fixed/welded to B), expressed in frame_B.
  /// @param[in] frame_A The frame that measures `v_ABp` (Bp's velocity in A).
  /// Note: It is natural to wonder why there is no parameter p_AoAp_A (similar
  /// to the parameter p_BoBp_B for frame_B).  There is no need for p_AoAp_A
  /// because Bp's velocity in A is defined as the derivative in frame A of
  /// Bp's position vector from _any_ point fixed to A.
  /// @param[in] frame_E The frame in which `v_ABp` is expressed on input and
  /// the frame in which the Jacobian `J𝑠_V_ABp` is expressed on output.
  /// @param[out] J𝑠_V_ABp_E Point Bp's spatial velocity Jacobian in frame A
  /// with respect to speeds 𝑠 (which is either q̇ or v), expressed in frame E.
  /// `J𝑠_V_ABp_E` is a `6 x n` matrix, where n is the number of elements in 𝑠.
  /// The Jacobian is a function of only generalized positions q (which are
  /// pulled from the context).
  /// Note: The returned `6 x n` matrix stores frame B's angular velocity
  /// Jacobian in A in rows 1-3 and stores point Bp's translational velocity
  /// Jacobian in A in rows 4-6, i.e., <pre>
  ///     J𝑠_w_AB_E = J𝑠_V_ABp_E.topRows<3>();
  ///     J𝑠_v_ABp_E = J𝑠_V_ABp_E.bottomRows<3>();
  /// </pre>
  /// Note: Consider CalcJacobianTranslationalVelocity() for multiple points
  /// fixed to frame B and consider CalcJacobianAngularVelocity() to calculate
  /// frame B's angular velocity Jacobian.
  /// @throws std::exception if `J𝑠_V_ABp_E` is nullptr or not sized `6 x n`.
  void CalcJacobianSpatialVelocity(const systems::Context<T>& context,
                                   JacobianWrtVariable with_respect_to,
                                   const Frame<T>& frame_B,
                                   const Eigen::Ref<const Vector3<T>>& p_BoBp_B,
                                   const Frame<T>& frame_A,
                                   const Frame<T>& frame_E,
                                   EigenPtr<MatrixX<T>> Js_V_ABp_E) const {
    this->ValidateContext(context);
    DRAKE_DEMAND(Js_V_ABp_E != nullptr);
    internal_tree().CalcJacobianSpatialVelocity(context, with_respect_to,
                                                frame_B, p_BoBp_B, frame_A,
                                                frame_E, Js_V_ABp_E);
  }

  /// Calculates J𝑠_w_AB, a frame B's angular velocity Jacobian in a frame A
  /// with respect to "speeds" 𝑠.
  /// <pre>
  ///      J𝑠_w_AB ≜ [ ∂(w_AB)/∂𝑠₁,  ...  ∂(w_AB)/∂𝑠ₙ ]    (n is j or k)
  ///      w_AB = J𝑠_w_AB ⋅ 𝑠          w_AB is linear in 𝑠 ≜ [𝑠₁ ... 𝑠ₙ]ᵀ
  /// </pre>
  /// `w_AB` is B's angular velocity in frame A and "speeds" 𝑠 is either
  /// q̇ ≜ [q̇₁ ... q̇ⱼ]ᵀ (time-derivatives of j generalized positions) or
  /// v ≜ [v₁ ... vₖ]ᵀ (k generalized velocities).
  ///
  /// @param[in] context The state of the multibody system.
  /// @param[in] with_respect_to Enum equal to JacobianWrtVariable::kQDot or
  /// JacobianWrtVariable::kV, indicating whether the Jacobian `J𝑠_w_AB` is
  /// partial derivatives with respect to 𝑠 = q̇ (time-derivatives of generalized
  /// positions) or with respect to 𝑠 = v (generalized velocities).
  /// @param[in] frame_B The frame B in `w_AB` (B's angular velocity in A).
  /// @param[in] frame_A The frame A in `w_AB` (B's angular velocity in A).
  /// @param[in] frame_E The frame in which `w_AB` is expressed on input and
  /// the frame in which the Jacobian `J𝑠_w_AB` is expressed on output.
  /// @param[out] J𝑠_w_AB_E Frame B's angular velocity Jacobian in frame A with
  /// respect to speeds 𝑠 (which is either q̇ or v), expressed in frame E.
  /// The Jacobian is a function of only generalized positions q (which are
  /// pulled from the context).  The previous definition shows `J𝑠_w_AB_E` is
  /// a matrix of size `3 x n`, where n is the number of elements in 𝑠.
  /// @throws std::exception if `J𝑠_w_AB_E` is nullptr or not of size `3 x n`.
  void CalcJacobianAngularVelocity(const systems::Context<T>& context,
                                   const JacobianWrtVariable with_respect_to,
                                   const Frame<T>& frame_B,
                                   const Frame<T>& frame_A,
                                   const Frame<T>& frame_E,
                                   EigenPtr<Matrix3X<T>> Js_w_AB_E) const {
    this->ValidateContext(context);
    DRAKE_DEMAND(Js_w_AB_E != nullptr);
    return internal_tree().CalcJacobianAngularVelocity(
        context, with_respect_to, frame_B, frame_A, frame_E, Js_w_AB_E);
  }

  /// For each point Bi affixed/welded to a frame B, calculates J𝑠_v_ABi, Bi's
  /// translational velocity Jacobian in frame A with respect to "speeds" 𝑠.
  /// <pre>
  ///      J𝑠_v_ABi ≜ [ ∂(v_ABi)/∂𝑠₁,  ...  ∂(v_ABi)/∂𝑠ₙ ]    (n is j or k)
  ///      v_ABi = J𝑠_v_ABi ⋅ 𝑠          v_ABi is linear in 𝑠 ≜ [𝑠₁ ... 𝑠ₙ]ᵀ
  /// </pre>
  /// `v_ABi` is Bi's translational velocity in frame A and "speeds" 𝑠 is either
  /// q̇ ≜ [q̇₁ ... q̇ⱼ]ᵀ (time-derivatives of j generalized positions) or
  /// v ≜ [v₁ ... vₖ]ᵀ (k generalized velocities).
  ///
  /// @param[in] context The state of the multibody system.
  /// @param[in] with_respect_to Enum equal to JacobianWrtVariable::kQDot or
  /// JacobianWrtVariable::kV, indicating whether the Jacobian `J𝑠_v_ABi` is
  /// partial derivatives with respect to 𝑠 = q̇ (time-derivatives of generalized
  /// positions) or with respect to 𝑠 = v (generalized velocities).
  /// @param[in] frame_B The frame on which point Bi is affixed/welded.
  /// @param[in] p_BoBi_B A position vector or list of p position vectors from
  /// Bo (frame_B's origin) to points Bi (regarded as affixed to B), where each
  /// position vector is expressed in frame_B.
  /// @param[in] frame_A The frame that measures `v_ABi` (Bi's velocity in A).
  /// Note: It is natural to wonder why there is no parameter p_AoAi_A (similar
  /// to the parameter p_BoBi_B for frame_B).  There is no need for p_AoAi_A
  /// because Bi's velocity in A is defined as the derivative in frame A of
  /// Bi's position vector from _any_ point affixed to A.
  /// @param[in] frame_E The frame in which `v_ABi` is expressed on input and
  /// the frame in which the Jacobian `J𝑠_v_ABi` is expressed on output.
  /// @param[out] J𝑠_v_ABi_E Point Bi's velocity Jacobian in frame A with
  /// respect to speeds 𝑠 (which is either q̇ or v), expressed in frame E.
  /// `J𝑠_v_ABi_E` is a `3*p x n` matrix, where p is the number of points Bi and
  /// n is the number of elements in 𝑠.  The Jacobian is a function of only
  /// generalized positions q (which are pulled from the context).
  /// @throws std::exception if `J𝑠_v_ABi_E` is nullptr or not sized `3*p x n`.
  /// @note When 𝑠 = q̇, `Jq̇_v_ABi = Jq_p_AoBi`.  In other words, point Bi's
  /// velocity Jacobian in frame A with respect to q̇ is equal to point Bi's
  /// position Jacobian from Ao (A's origin) in frame A with respect to q. <pre>
  /// [∂(v_ABi)/∂q̇₁,  ...  ∂(v_ABi)/∂q̇ⱼ] = [∂(p_AoBi)/∂q₁,  ...  ∂(p_AoBi)/∂qⱼ]
  /// </pre>
  /// Note: Each partial derivative of p_AoBi is taken in frame A.
  /// @see CalcJacobianPositionVector() for details on Jq_p_AoBi.
  void CalcJacobianTranslationalVelocity(
      const systems::Context<T>& context, JacobianWrtVariable with_respect_to,
      const Frame<T>& frame_B, const Eigen::Ref<const Matrix3X<T>>& p_BoBi_B,
      const Frame<T>& frame_A, const Frame<T>& frame_E,
      EigenPtr<MatrixX<T>> Js_v_ABi_E) const {
    // TODO(amcastro-tri): provide the Jacobian-times-vector operation.  For
    // some applications it is all we need and it is more efficient to compute.
    this->ValidateContext(context);
    DRAKE_DEMAND(Js_v_ABi_E != nullptr);
    internal_tree().CalcJacobianTranslationalVelocity(
        context, with_respect_to, frame_B, frame_B, p_BoBi_B, frame_A, frame_E,
        Js_v_ABi_E);
  }

  /// For each point Bi affixed/welded to a frame B, calculates Jq_p_AoBi, Bi's
  /// position vector Jacobian in frame A with respect to the generalized
  /// positions q ≜ [q₁ ... qₙ]ᵀ as
  /// <pre>
  ///      Jq_p_AoBi ≜ [ ᴬ∂(p_AoBi)/∂q₁,  ...  ᴬ∂(p_AoBi)/∂qₙ ]
  /// </pre>
  /// where p_AoBi is Bi's position vector from point Ao (frame A's origin) and
  /// ᴬ∂(p_AoBi)/∂qᵣ denotes the partial derivative in frame A of p_AoBi with
  /// respect to the generalized position qᵣ, where qᵣ is one of q₁ ... qₙ.
  /// @param[in] context The state of the multibody system.
  /// @param[in] frame_B The frame on which point Bi is affixed/welded.
  /// @param[in] p_BoBi_B A position vector or list of k position vectors from
  /// Bo (frame_B's origin) to points Bi (Bi is regarded as affixed to B), where
  /// each position vector is expressed in frame_B.
  /// @param[in] frame_A The frame in which partial derivatives are calculated
  /// and the frame in which point Ao is affixed.
  /// @param[in] frame_E The frame in which the Jacobian Jq_p_AoBi is expressed
  /// on output.
  /// @param[out] Jq_p_AoBi_E Point Bi's position vector Jacobian in frame A
  /// with generalized positions q, expressed in frame E. Jq_p_AoBi_E is a
  /// `3*k x n` matrix, where k is the number of points Bi and n is the number
  /// of elements in q.  The Jacobian is a function of only generalized
  /// positions q (which are pulled from the context).
  /// @throws std::exception if Jq_p_AoBi_E is nullptr or not sized `3*k x n`.
  /// @note Jq̇_v_ABi = Jq_p_AoBi.  In other words, point Bi's velocity Jacobian
  /// in frame A with respect to q̇ is equal to point Bi's position vector
  /// Jacobian in frame A with respect to q.
  /// <pre>
  /// [∂(v_ABi)/∂q̇₁, ... ∂(v_ABi)/∂q̇ₙ] = [ᴬ∂(p_AoBi)/∂q₁, ... ᴬ∂(p_AoBi)/∂qₙ]
  /// </pre>
  /// @see CalcJacobianTranslationalVelocity() for details on Jq̇_v_ABi.
  /// Note: Jq_p_AaBi = Jq_p_AoBi, where point Aa is _any_ point fixed/welded to
  /// frame A, i.e., this calculation's result is the same if point Ao is
  /// replaced with any point fixed on frame A.
  void CalcJacobianPositionVector(const systems::Context<T>& context,
                                  const Frame<T>& frame_B,
                                  const Eigen::Ref<const Matrix3X<T>>& p_BoBi_B,
                                  const Frame<T>& frame_A,
                                  const Frame<T>& frame_E,
                                  EigenPtr<MatrixX<T>> Jq_p_AoBi_E) const {
    // TODO(mitiguy) Consider providing the Jacobian-times-vector operation.
    //  Sometimes it is all that is needed and more efficient to compute.
    this->ValidateContext(context);
    DRAKE_DEMAND(Jq_p_AoBi_E != nullptr);
    internal_tree().CalcJacobianTranslationalVelocity(
        context, JacobianWrtVariable::kQDot, frame_B, frame_B, p_BoBi_B,
        frame_A, frame_E, Jq_p_AoBi_E);
  }

  /// Calculates J𝑠_v_ACcm_E, point Ccm's translational velocity Jacobian in
  /// frame A with respect to "speeds" 𝑠, expressed in frame E, where point CCm
  /// is the center of mass of the system of all non-world bodies contained in
  /// `this` MultibodyPlant.
  /// @param[in] context contains the state of the model.
  /// @param[in] with_respect_to Enum equal to JacobianWrtVariable::kQDot or
  /// JacobianWrtVariable::kV, indicating whether the Jacobian `J𝑠_v_ACcm_E` is
  /// partial derivatives with respect to 𝑠 = q̇ (time-derivatives of generalized
  /// positions) or with respect to 𝑠 = v (generalized velocities).
  /// @param[in] frame_A The frame in which the translational velocity
  /// v_ACcm and its Jacobian J𝑠_v_ACcm are measured.
  /// @param[in] frame_E The frame in which the Jacobian J𝑠_v_ACcm is
  /// expressed on output.
  /// @param[out] J𝑠_v_ACcm_E Point Ccm's translational velocity Jacobian in
  /// frame A with respect to speeds 𝑠 (𝑠 = q̇ or 𝑠 = v), expressed in frame E.
  /// J𝑠_v_ACcm_E is a 3 x n matrix, where n is the number of elements in 𝑠.
  /// The Jacobian is a function of only generalized positions q (which are
  /// pulled from the context).
  /// @throws std::exception if CCm does not exist, which occurs if there
  /// are no massive bodies in MultibodyPlant (except world_body()).
  /// @throws std::exception if mₛ ≤ 0 (where mₛ is the mass of all non-world
  /// bodies contained in `this` MultibodyPlant).
  void CalcJacobianCenterOfMassTranslationalVelocity(
      const systems::Context<T>& context, JacobianWrtVariable with_respect_to,
      const Frame<T>& frame_A, const Frame<T>& frame_E,
      EigenPtr<Matrix3X<T>> Js_v_ACcm_E) const {
    this->ValidateContext(context);
    DRAKE_DEMAND(Js_v_ACcm_E != nullptr);
    internal_tree().CalcJacobianCenterOfMassTranslationalVelocity(
        context, with_respect_to, frame_A, frame_E, Js_v_ACcm_E);
  }

  /// Calculates J𝑠_v_ACcm_E, point Ccm's translational velocity Jacobian in
  /// frame A with respect to "speeds" 𝑠, expressed in frame E, where point CCm
  /// is the center of mass of the system of all non-world bodies contained in
  /// model_instances.
  /// @param[in] context contains the state of the model.
  /// @param[in] model_instances Vector of selected model instances.  If a model
  /// instance is repeated in the vector (unusual), it is only counted once.
  /// @param[in] with_respect_to Enum equal to JacobianWrtVariable::kQDot or
  /// JacobianWrtVariable::kV, indicating whether the Jacobian `J𝑠_v_ACcm_E` is
  /// partial derivatives with respect to 𝑠 = q̇ (time-derivatives of generalized
  /// positions) or with respect to 𝑠 = v (generalized velocities).
  /// @param[in] frame_A The frame in which the translational velocity
  /// v_ACcm and its Jacobian J𝑠_v_ACcm are measured.
  /// @param[in] frame_E The frame in which the Jacobian J𝑠_v_ACcm is
  /// expressed on output.
  /// @param[out] J𝑠_v_ACcm_E Point Ccm's translational velocity Jacobian in
  /// frame A with respect to speeds 𝑠 (𝑠 = q̇ or 𝑠 = v), expressed in frame E.
  /// J𝑠_v_ACcm_E is a 3 x n matrix, where n is the number of elements in 𝑠.
  /// The Jacobian is a function of only generalized positions q (which are
  /// pulled from the context).
  /// @throws std::exception if mₛ ≤ 0 (where mₛ is the mass of all non-world
  /// bodies contained in model_instances).
  /// @throws std::exception if model_instances is empty or only has world body.
  /// @note The world_body() is ignored.  J𝑠_v_ACcm_ = ∑ (mᵢ Jᵢ) / mₛ, where
  /// mₛ = ∑ mᵢ, mᵢ is the mass of the iᵗʰ body contained in model_instances,
  /// and Jᵢ is Bcm's translational velocity Jacobian in frame A, expressed in
  /// frame E (Bcm is the center of mass of the iᵗʰ body).
  void CalcJacobianCenterOfMassTranslationalVelocity(
      const systems::Context<T>& context,
      const std::vector<ModelInstanceIndex>& model_instances,
      JacobianWrtVariable with_respect_to, const Frame<T>& frame_A,
      const Frame<T>& frame_E, EigenPtr<Matrix3X<T>> Js_v_ACcm_E) const {
    this->ValidateContext(context);
    DRAKE_DEMAND(Js_v_ACcm_E != nullptr);
    internal_tree().CalcJacobianCenterOfMassTranslationalVelocity(
        context, model_instances, with_respect_to, frame_A, frame_E,
        Js_v_ACcm_E);
  }

  /// Calculates abias_ACcm_E, point Ccm's translational "bias" acceleration
  /// term in frame A with respect to "speeds" 𝑠, expressed in frame E, where
  /// point Ccm is the composite center of mass of the system of all bodies
  /// (except world_body()) in the MultibodyPlant. abias_ACcm is the part of
  /// a_ACcm (Ccm's translational acceleration) that does not multiply ṡ, equal
  /// to abias_ACcm = J̇𝑠_v_ACcm ⋅ s. This allows a_ACcm to be written as
  /// a_ACcm = J𝑠_v_ACcm ⋅ ṡ + abias_ACcm.
  ///
  /// @param[in] context The state of the multibody system.
  /// @param[in] with_respect_to Enum equal to JacobianWrtVariable::kQDot or
  /// JacobianWrtVariable::kV, indicating whether the Jacobian `abias_ACcm` is
  /// partial derivatives with respect to 𝑠 = q̇ (time-derivatives of generalized
  /// positions) or with respect to 𝑠 = v (generalized velocities).
  /// @param[in] frame_A The frame in which abias_ACcm is measured.
  /// @param[in] frame_E The frame in which abias_ACcm is expressed on output.
  /// @retval abias_ACcm_E Point Ccm's translational "bias" acceleration term
  /// in frame A with respect to "speeds" 𝑠, expressed in frame E.
  /// @throws std::exception if Ccm does not exist, which occurs if there
  /// are no massive bodies in MultibodyPlant (except world_body()).
  /// @throws std::exception if composite_mass <= 0, where composite_mass is
  /// the total mass of all bodies except world_body() in MultibodyPlant.
  /// @throws std::exception if frame_A is not the world frame.
  Vector3<T> CalcBiasCenterOfMassTranslationalAcceleration(
      const systems::Context<T>& context, JacobianWrtVariable with_respect_to,
      const Frame<T>& frame_A, const Frame<T>& frame_E) const {
    // TODO(yangwill): Add an optional parameter to calculate this for a
    // subset of bodies instead of the full system
    this->ValidateContext(context);
    return internal_tree().CalcBiasCenterOfMassTranslationalAcceleration(
        context, with_respect_to, frame_A, frame_E);
  }

  /// This method allows users to map the state of `this` model, x, into a
  /// vector of selected state xₛ with a given preferred ordering.
  /// The mapping, or selection, is returned in the form of a selector matrix
  /// Sx such that `xₛ = Sx⋅x`. The size nₛ of xₛ is always smaller or equal
  /// than the size of the full state x. That is, a user might be interested in
  /// only a given portion of the full state x.
  ///
  /// This selection matrix is particularly useful when adding PID control
  /// on a portion of the state, see systems::controllers::PidController.
  ///
  /// A user specifies the preferred order in xₛ via `user_to_joint_index_map`.
  /// The selected state is built such that selected positions are followed
  /// by selected velocities, as in `xₛ = [qₛ, vₛ]`.
  /// The positions in qₛ are a concatenation of the positions for each joint
  /// in the order they appear in `user_to_joint_index_map`. That is, the
  /// positions for `user_to_joint_index_map[0]` are first, followed by the
  /// positions for `user_to_joint_index_map[1]`, etc. Similarly for the
  /// selected velocities vₛ.
  ///
  /// @throws std::exception if there are repeated indexes in
  /// `user_to_joint_index_map`.
  MatrixX<double> MakeStateSelectorMatrix(
      const std::vector<JointIndex>& user_to_joint_index_map) const {
    // TODO(amcastro-tri): consider having an extra `free_body_index_map`
    // so that users could also re-order free bodies if they wanted to.
    return internal_tree().MakeStateSelectorMatrix(user_to_joint_index_map);
  }

  /// This method allows user to map a vector `uₛ` containing the actuation
  /// for a set of selected actuators into the vector u containing the actuation
  /// values for `this` full model.
  /// The mapping, or selection, is returned in the form of a selector matrix
  /// Su such that `u = Su⋅uₛ`. The size nₛ of uₛ is always smaller or equal
  /// than the size of the full vector of actuation values u. That is, a user
  /// might be interested in only a given subset of actuators in the model.
  ///
  /// This selection matrix is particularly useful when adding PID control
  /// on a portion of the state, see systems::controllers::PidController.
  ///
  /// A user specifies the preferred order in uₛ via
  /// `user_to_actuator_index_map`. The actuation values in uₛ are a
  /// concatenation of the values for each actuator in the order they appear in
  /// `user_to_actuator_index_map`.
  /// The full vector of actuation values u is ordered by JointActuatorIndex.
  MatrixX<double> MakeActuatorSelectorMatrix(
      const std::vector<JointActuatorIndex>& user_to_actuator_index_map) const {
    return internal_tree().MakeActuatorSelectorMatrix(
        user_to_actuator_index_map);
  }

  /// This method creates an actuation matrix B mapping a vector of actuation
  /// values u into generalized forces `tau_u = B * u`, where B is a matrix of
  /// size `nv x nu` with `nu` equal to num_actuators() and `nv` equal to
  /// num_velocities().
  /// The vector u of actuation values is of size num_actuators(). For a given
  /// JointActuator, `u[JointActuator::index()]` stores the value for the
  /// external actuation corresponding to that actuator. `tau_u` on the other
  /// hand is indexed by generalized velocity indexes according to
  /// `Joint::velocity_start()`.
  /// @warning B is a permutation matrix. While making a permutation has
  /// `O(n)` complexity, making a full B matrix has `O(n²)` complexity. For most
  /// applications this cost can be neglected but it could become significant
  /// for very large systems.
  MatrixX<T> MakeActuationMatrix() const;

  /// Alternative signature to build an actuation selector matrix `Su` such
  /// that `u = Su⋅uₛ`, where u is the vector of actuation values for the full
  /// model (ordered by JointActuatorIndex) and uₛ is a vector of actuation
  /// values for the actuators acting on the joints listed by
  /// `user_to_joint_index_map`. It is assumed that all joints referenced by
  /// `user_to_joint_index_map` are actuated.
  /// See MakeActuatorSelectorMatrix(const std::vector<JointActuatorIndex>&) for
  /// details.
  /// @throws std::exception if any of the joints in
  /// `user_to_joint_index_map` does not have an actuator.
  MatrixX<double> MakeActuatorSelectorMatrix(
      const std::vector<JointIndex>& user_to_joint_index_map) const {
    return internal_tree().MakeActuatorSelectorMatrix(user_to_joint_index_map);
  }
  /// @} <!-- System matrix computations -->

  /// @anchor mbp_introspection
  /// @name                    Introspection
  /// These methods allow a user to query whether a given multibody element is
  /// part of this plant's model. These queries can be performed at any time
  /// during the lifetime of a %MultibodyPlant model, i.e. there is no
  /// restriction on whether they must be called before or after Finalize().
  /// These queries can be performed while new multibody elements are
  /// being added to the model.
  /// These methods allow a user to retrieve a reference to a multibody element
  /// by its name. An exception is thrown if there is no element with the
  /// requested name.
  ///
  /// If the named element is present in more than one model instance and a
  /// model instance is not explicitly specified, std::logic_error is thrown.
  /// @{

  /// The time step (or period) used to model `this` plant as a discrete system
  /// with periodic updates. Returns 0 (zero) if the plant is modeled as a
  /// continuous system.
  /// This property of the plant is specified at construction and therefore this
  /// query can be performed either pre- or post-finalize, see Finalize().
  /// @see MultibodyPlant::MultibodyPlant(double)
  double time_step() const { return time_step_; }

  /// Returns `true` if this %MultibodyPlant was finalized with a call to
  /// Finalize().
  /// @see Finalize().
  bool is_finalized() const { return internal_tree().topology_is_valid(); }

  /// Returns a constant reference to the *world* body.
  const RigidBody<T>& world_body() const {
    return internal_tree().world_body();
  }

  /// Returns a constant reference to the *world* frame.
  const BodyFrame<T>& world_frame() const {
    return internal_tree().world_frame();
  }

  /// Returns the number of bodies in the model, including the "world" body,
  /// which is always part of the model.
  /// @see AddRigidBody().
  int num_bodies() const { return internal_tree().num_bodies(); }

  /// Returns a constant reference to the body with unique index `body_index`.
  /// @throws std::exception if `body_index` does not correspond to a body in
  /// this model.
  const Body<T>& get_body(BodyIndex body_index) const {
    return internal_tree().get_body(body_index);
  }

  /// Returns `true` if @p body is anchored (i.e. the kinematic path between
  /// @p body and the world only contains weld joints.)
  /// @throws std::exception if called pre-finalize.
  bool IsAnchored(const Body<T>& body) const {
    DRAKE_MBP_THROW_IF_NOT_FINALIZED();
    return internal_tree().get_topology().IsBodyAnchored(body.index());
  }

  /// @returns `true` if a body named `name` was added to the %MultibodyPlant.
  /// @see AddRigidBody().
  ///
  /// @throws std::exception if the body name occurs in multiple model
  /// instances.
  bool HasBodyNamed(std::string_view name) const {
    return internal_tree().HasBodyNamed(name);
  }

  /// @returns The total number of bodies (across all model instances) with the
  /// given name.
  int NumBodiesWithName(std::string_view name) const {
    return internal_tree().NumBodiesWithName(name);
  }

  /// @returns `true` if a body named `name` was added to the %MultibodyPlant
  /// in @p model_instance.
  /// @see AddRigidBody().
  ///
  /// @throws std::exception if @p model_instance is not valid for this model.
  bool HasBodyNamed(std::string_view name,
                    ModelInstanceIndex model_instance) const {
    return internal_tree().HasBodyNamed(name, model_instance);
  }

  /// Returns a constant reference to a body that is identified
  /// by the string `name` in `this` %MultibodyPlant.
  /// @throws std::exception if there is no body with the requested name.
  /// @throws std::exception if the body name occurs in multiple model
  /// instances.
  /// @see HasBodyNamed() to query if there exists a body in `this`
  /// %MultibodyPlant with a given specified name.
  const Body<T>& GetBodyByName(std::string_view name) const {
    return internal_tree().GetBodyByName(name);
  }

  /// Returns a constant reference to the body that is uniquely identified
  /// by the string `name` and @p model_instance in `this` %MultibodyPlant.
  /// @throws std::exception if there is no body with the requested name.
  /// @see HasBodyNamed() to query if there exists a body in `this`
  /// %MultibodyPlant with a given specified name.
  const Body<T>& GetBodyByName(std::string_view name,
                               ModelInstanceIndex model_instance) const {
    return internal_tree().GetBodyByName(name, model_instance);
  }

  /// Returns a list of body indices associated with `model_instance`.
  std::vector<BodyIndex> GetBodyIndices(
      ModelInstanceIndex model_instance) const {
    return internal_tree().GetBodyIndices(model_instance);
  }

  /// Returns a constant reference to a rigid body that is identified
  /// by the string `name` in `this` model.
  /// @throws std::exception if there is no body with the requested name.
  /// @throws std::exception if the body name occurs in multiple model
  /// instances.
  /// @throws std::exception if the requested body is not a RigidBody.
  /// @see HasBodyNamed() to query if there exists a body in `this` model with a
  /// given specified name.
  const RigidBody<T>& GetRigidBodyByName(std::string_view name) const {
    return internal_tree().GetRigidBodyByName(name);
  }

  /// Returns a constant reference to the rigid body that is uniquely identified
  /// by the string `name` in @p model_instance.
  /// @throws std::exception if there is no body with the requested name.
  /// @throws std::exception if the requested body is not a RigidBody.
  /// @throws std::exception if @p model_instance is not valid for this
  ///         model.
  /// @see HasBodyNamed() to query if there exists a body in `this` model with a
  /// given specified name.
  const RigidBody<T>& GetRigidBodyByName(
      std::string_view name, ModelInstanceIndex model_instance) const {
    return internal_tree().GetRigidBodyByName(name, model_instance);
  }

  /// Returns all bodies that are transitively welded, or rigidly affixed, to
  /// `body`, per these two definitions:
  ///
  /// 1. A body is always considered welded to itself.
  /// 2. Two unique bodies are considered welded together exclusively by the
  /// presence of a weld joint, not by other constructs that prevent mobility
  /// (e.g. constraints).
  ///
  /// This method can be called at any time during the lifetime of `this` plant,
  /// either pre- or post-finalize, see Finalize().
  ///
  /// Meant to be used with `CollectRegisteredGeometries`.
  ///
  /// The following example demonstrates filtering collisions between all
  /// bodies rigidly affixed to a door (which could be moving) and all bodies
  /// rigidly affixed to the world:
  /// @code
  /// GeometrySet g_world = plant.CollectRegisteredGeometries(
  ///     plant.GetBodiesWeldedTo(plant.world_body()));
  /// GeometrySet g_door = plant.CollectRegisteredGeometries(
  ///     plant.GetBodiesWeldedTo(plant.GetBodyByName("door")));
  /// scene_graph.ExcludeCollisionsBetweeen(g_world, g_door);
  /// @endcode
  /// @note Usages akin to this example may introduce redundant collision
  /// filtering; this will not have a functional impact, but may have a minor
  /// performance impact.
  ///
  /// @returns all bodies rigidly fixed to `body`. This does not return the
  /// bodies in any prescribed order.
  /// @throws std::exception if `body` is not part of this plant.
  std::vector<const Body<T>*> GetBodiesWeldedTo(const Body<T>& body) const;

  /// Returns all bodies whose kinematics are transitively affected by the given
  /// vector of joints. The affected bodies are returned in increasing order of
  /// body indexes. Note that this is a kinematic relationship rather than a
  /// dynamic one. For example, if one of the inboard joints is a free (6dof)
  /// joint, the kinematic influence is still felt even though dynamically
  /// there would be no influence on the outboard body.
  /// This function can be only be called post-finalize, see Finalize().
  /// @throws std::exception if any of the given joint has an invalid index,
  /// doesn't correspond to a mobilizer, or is welded.
  std::vector<BodyIndex> GetBodiesKinematicallyAffectedBy(
      const std::vector<JointIndex>& joint_indexes) const;

  /// Returns the number of joints in the model.
  /// @see AddJoint().
  int num_joints() const { return internal_tree().num_joints(); }

  /// Returns a constant reference to the joint with unique index `joint_index`.
  /// @throws std::exception when `joint_index` does not correspond to a
  /// joint in this model.
  const Joint<T>& get_joint(JointIndex joint_index) const {
    return internal_tree().get_joint(joint_index);
  }

  /// @returns `true` if a joint named `name` was added to this model.
  /// @see AddJoint().
  /// @throws std::exception if the joint name occurs in multiple model
  /// instances.
  bool HasJointNamed(std::string_view name) const {
    return internal_tree().HasJointNamed(name);
  }

  /// @returns `true` if a joint named `name` was added to @p model_instance.
  /// @see AddJoint().
  /// @throws std::exception if @p model_instance is not valid for this model.
  bool HasJointNamed(std::string_view name,
                     ModelInstanceIndex model_instance) const {
    return internal_tree().HasJointNamed(name, model_instance);
  }

  /// Returns a mutable reference to the joint with unique index `joint_index`.
  /// @throws std::exception when `joint_index` does not correspond to a
  /// joint in this model.
  Joint<T>& get_mutable_joint(JointIndex joint_index) {
    return this->mutable_tree().get_mutable_joint(joint_index);
  }

  /// Returns a list of joint indices associated with `model_instance`.
  std::vector<JointIndex> GetJointIndices(
      ModelInstanceIndex model_instance) const {
    return internal_tree().GetJointIndices(model_instance);
  }

  /// Returns a list of joint actuator indices associated with `model_instance`.
  /// The vector is ordered by monotonically increasing @ref JointActuatorIndex.
  /// @throws std::exception if called pre-finalize.
  std::vector<JointActuatorIndex> GetJointActuatorIndices(
      ModelInstanceIndex model_instance) const {
    return internal_tree().GetJointActuatorIndices(model_instance);
  }

  /// Returns a list of actuated joint indices associated with `model_instance`.
  /// @throws std::exception if called pre-finalize.
  std::vector<JointIndex> GetActuatedJointIndices(
      ModelInstanceIndex model_instance) const {
    return internal_tree().GetActuatedJointIndices(model_instance);
  }

  /// Returns a constant reference to a joint that is identified
  /// by the string `name` in `this` %MultibodyPlant.  If the optional
  /// template argument is supplied, then the returned value is downcast to
  /// the specified `JointType`.
  /// @tparam JointType The specific type of the Joint to be retrieved. It must
  /// be a subclass of Joint.
  /// @throws std::exception if the named joint is not of type `JointType` or
  /// if there is no Joint with that name.
  /// @throws std::exception if @p model_instance is not valid for this model.
  /// @see HasJointNamed() to query if there exists a joint in `this`
  /// %MultibodyPlant with a given specified name.
  template <template <typename> class JointType = Joint>
  const JointType<T>& GetJointByName(
      std::string_view name,
      std::optional<ModelInstanceIndex> model_instance = std::nullopt) const {
    return internal_tree().template GetJointByName<JointType>(name,
                                                              model_instance);
  }

  /// A version of GetJointByName that returns a mutable reference.
  /// @see GetJointByName.
  template <template <typename> class JointType = Joint>
  JointType<T>& GetMutableJointByName(
      std::string_view name,
      std::optional<ModelInstanceIndex> model_instance = std::nullopt) {
    return this->mutable_tree().template GetMutableJointByName<JointType>(
        name, model_instance);
  }

  /// Returns the number of Frame objects in this model.
  /// Frames include body frames associated with each of the bodies,
  /// including the _world_ body. This means the minimum number of frames is
  /// one.
  int num_frames() const { return internal_tree().num_frames(); }

  /// Returns a constant reference to the frame with unique index `frame_index`.
  /// @throws std::exception if `frame_index` does not correspond to a frame in
  /// this plant.
  const Frame<T>& get_frame(FrameIndex frame_index) const {
    return internal_tree().get_frame(frame_index);
  }

  /// @returns `true` if a frame named `name` was added to the model.
  /// @see AddFrame().
  /// @throws std::exception if the frame name occurs in multiple model
  /// instances.
  bool HasFrameNamed(std::string_view name) const {
    return internal_tree().HasFrameNamed(name);
  }

  /// @returns `true` if a frame named `name` was added to @p model_instance.
  /// @see AddFrame().
  /// @throws std::exception if @p model_instance is not valid for this model.
  bool HasFrameNamed(std::string_view name,
                     ModelInstanceIndex model_instance) const {
    return internal_tree().HasFrameNamed(name, model_instance);
  }

  /// Returns a constant reference to a frame that is identified by the
  /// string `name` in `this` model.
  /// @throws std::exception if there is no frame with the requested name.
  /// @throws std::exception if the frame name occurs in multiple model
  /// instances.
  /// @see HasFrameNamed() to query if there exists a frame in `this` model with
  /// a given specified name.
  const Frame<T>& GetFrameByName(std::string_view name) const {
    return internal_tree().GetFrameByName(name);
  }

  /// Returns a constant reference to the frame that is uniquely identified
  /// by the string `name` in @p model_instance.
  /// @throws std::exception if there is no frame with the requested name.
  /// @throws std::exception if @p model_instance is not valid for this
  ///         model.
  /// @see HasFrameNamed() to query if there exists a frame in `this` model with
  /// a given specified name.
  const Frame<T>& GetFrameByName(std::string_view name,
                                 ModelInstanceIndex model_instance) const {
    return internal_tree().GetFrameByName(name, model_instance);
  }

  /// Returns a list of frame indices associated with `model_instance`.
  std::vector<FrameIndex> GetFrameIndices(
      ModelInstanceIndex model_instance) const {
    return internal_tree().GetFrameIndices(model_instance);
  }

  /// Returns the number of joint actuators in the model.
  /// @see AddJointActuator().
  int num_actuators() const { return internal_tree().num_actuators(); }

  /// Returns the number of actuators for a specific model instance.
  /// @throws std::exception if called pre-finalize.
  int num_actuators(ModelInstanceIndex model_instance) const {
    return internal_tree().num_actuators(model_instance);
  }

  /// Returns the total number of actuated degrees of freedom.
  /// That is, the vector of actuation values u has this size.
  /// See AddJointActuator().
  int num_actuated_dofs() const { return internal_tree().num_actuated_dofs(); }

  /// Returns the total number of actuated degrees of freedom for a specific
  /// model instance.  That is, the vector of actuation values u has this size.
  /// See AddJointActuator().
  /// @throws std::exception if called pre-finalize.
  int num_actuated_dofs(ModelInstanceIndex model_instance) const {
    return internal_tree().num_actuated_dofs(model_instance);
  }

  /// Returns a constant reference to the joint actuator with unique index
  /// `actuator_index`.
  /// @throws std::exception if `actuator_index` does not correspond to a joint
  /// actuator in this tree.
  const JointActuator<T>& get_joint_actuator(
      JointActuatorIndex actuator_index) const {
    return internal_tree().get_joint_actuator(actuator_index);
  }

  /// Returns a mutable reference to the joint actuator with unique index
  /// `actuator_index`.
  /// @throws std::exception if `actuator_index` does not correspond to a joint
  /// actuator in this tree.
  JointActuator<T>& get_mutable_joint_actuator(
      JointActuatorIndex actuator_index) const {
    return internal_tree().get_mutable_joint_actuator(actuator_index);
  }

  /// @returns `true` if an actuator named `name` was added to this model.
  /// @see AddJointActuator().
  /// @throws std::exception if the actuator name occurs in multiple model
  /// instances.
  bool HasJointActuatorNamed(std::string_view name) const {
    return internal_tree().HasJointActuatorNamed(name);
  }

  /// @returns `true` if an actuator named `name` was added to
  /// @p model_instance.
  /// @see AddJointActuator().
  /// @throws std::exception if @p model_instance is not valid for this model.
  bool HasJointActuatorNamed(std::string_view name,
                             ModelInstanceIndex model_instance) const {
    return internal_tree().HasJointActuatorNamed(name, model_instance);
  }

  /// Returns a constant reference to an actuator that is identified
  /// by the string `name` in `this` %MultibodyPlant.
  /// @throws std::exception if there is no actuator with the requested name.
  /// @throws std::exception if the actuator name occurs in multiple model
  /// instances.
  /// @see HasJointActuatorNamed() to query if there exists an actuator in
  /// `this` %MultibodyPlant with a given specified name.
  const JointActuator<T>& GetJointActuatorByName(std::string_view name) const {
    return internal_tree().GetJointActuatorByName(name);
  }

  /// Returns a constant reference to the actuator that is uniquely identified
  /// by the string `name` and @p model_instance in `this` %MultibodyPlant.
  /// @throws std::exception if there is no actuator with the requested name.
  /// @throws std::exception if @p model_instance is not valid for this model.
  /// @see HasJointActuatorNamed() to query if there exists an actuator in
  /// `this` %MultibodyPlant with a given specified name.
  const JointActuator<T>& GetJointActuatorByName(
      std::string_view name, ModelInstanceIndex model_instance) const {
    return internal_tree().GetJointActuatorByName(name, model_instance);
  }

  /// Returns the number of ForceElement objects.
  /// @see AddForceElement().
  int num_force_elements() const {
    return internal_tree().num_force_elements();
  }

  /// Returns a constant reference to the force element with unique index
  /// `force_element_index`.
  /// @throws std::exception when `force_element_index` does not correspond
  /// to a force element in this model.
  const ForceElement<T>& get_force_element(
      ForceElementIndex force_element_index) const {
    return internal_tree().get_force_element(force_element_index);
  }

  /// Returns a constant reference to a force element identified by its unique
  /// index in `this` %MultibodyPlant.  If the optional template argument is
  /// supplied, then the returned value is downcast to the specified
  /// `ForceElementType`.
  /// @tparam ForceElementType The specific type of the ForceElement to be
  /// retrieved. It must be a subclass of ForceElement.
  /// @throws std::exception if the force element is not of type
  /// `ForceElementType` or if there is no ForceElement with that index.
  template <template <typename> class ForceElementType = ForceElement>
  const ForceElementType<T>& GetForceElement(
      ForceElementIndex force_element_index) const {
    return internal_tree().template GetForceElement<ForceElementType>(
        force_element_index);
  }

  /// @returns `true` iff gravity is enabled for `model_instance`.
  /// @see set_gravity_enabled().
  /// @throws std::exception if the model instance is invalid.
  bool is_gravity_enabled(ModelInstanceIndex model_instance) const;

  /// Sets is_gravity_enabled() for `model_instance` to `is_enabled`.
  /// The effect of `is_enabled = false` is effectively equivalent to disabling
  /// (or making zero) gravity for all bodies in the specified model instance.
  /// By default is_gravity_enabled() equals `true` for all model instances.
  /// @throws std::exception if called post-finalize.
  /// @throws std::exception if the model instance is invalid.
  void set_gravity_enabled(ModelInstanceIndex model_instance, bool is_enabled);

  /// An accessor to the current gravity field.
  const UniformGravityFieldElement<T>& gravity_field() const {
    return internal_tree().gravity_field();
  }

  // TODO(amastro-tri): mutation of the model should only be allowed
  // pre-finalize.
  /// A mutable accessor to the current gravity field.
  UniformGravityFieldElement<T>& mutable_gravity_field() {
    return this->mutable_tree().mutable_gravity_field();
  }

  /// Returns the number of model instances in the model.
  /// @see AddModelInstance().
  int num_model_instances() const {
    return internal_tree().num_model_instances();
  }

  /// Returns the name of a `model_instance`.
  /// @throws std::exception when `model_instance` does not correspond to a
  /// model in this model.
  const std::string& GetModelInstanceName(
      ModelInstanceIndex model_instance) const {
    return internal_tree().GetModelInstanceName(model_instance);
  }

  /// @returns `true` if a model instance named `name` was added to this model.
  /// @see AddModelInstance().
  bool HasModelInstanceNamed(std::string_view name) const {
    return internal_tree().HasModelInstanceNamed(name);
  }

  /// Returns the index to the model instance that is uniquely identified
  /// by the string `name` in `this` %MultibodyPlant.
  /// @throws std::exception if there is no instance with the requested name.
  /// @see HasModelInstanceNamed() to query if there exists an instance in
  /// `this` %MultibodyPlant with a given specified name.
  ModelInstanceIndex GetModelInstanceByName(std::string_view name) const {
    return internal_tree().GetModelInstanceByName(name);
  }

  /// Returns a Graphviz string describing the topology of this plant.
  /// To render the string, use the Graphviz tool, ``dot``.
  /// http://www.graphviz.org/
  ///
  /// Note: this method can be called either before or after `Finalize()`.
  std::string GetTopologyGraphvizString() const;

  /// Returns the size of the generalized position vector q for this model.
  /// @throws std::exception if called pre-finalize.
  int num_positions() const { return internal_tree().num_positions(); }

  /// Returns the size of the generalized position vector qᵢ for model
  /// instance i.
  /// @throws std::exception if called pre-finalize.
  int num_positions(ModelInstanceIndex model_instance) const {
    return internal_tree().num_positions(model_instance);
  }

  /// Returns the size of the generalized velocity vector v for this model.
  /// @throws std::exception if called pre-finalize.
  int num_velocities() const { return internal_tree().num_velocities(); }

  /// Returns the size of the generalized velocity vector vᵢ for model
  /// instance i.
  /// @throws std::exception if called pre-finalize.
  int num_velocities(ModelInstanceIndex model_instance) const {
    return internal_tree().num_velocities(model_instance);
  }

  // N.B. The state in the Context may at some point contain values such as
  // integrated power and other discrete states, hence the specific name.
  /// Returns the size of the multibody system state vector x = [q v]. This
  /// will be `num_positions()` plus `num_velocities()`.
  /// @throws std::exception if called pre-finalize.
  int num_multibody_states() const { return internal_tree().num_states(); }

  /// Returns the size of the multibody system state vector xᵢ = [qᵢ vᵢ] for
  /// model instance i. (Here qᵢ ⊆ q and vᵢ ⊆ v.)
  /// will be `num_positions(model_instance)` plus
  /// `num_velocities(model_instance)`.
  /// @throws std::exception if called pre-finalize.
  int num_multibody_states(ModelInstanceIndex model_instance) const {
    return internal_tree().num_states(model_instance);
  }

  /// Returns a vector of size `num_positions()` containing the lower position
  /// limits for every generalized position coordinate. These include joint and
  /// free body coordinates. Any unbounded or unspecified limits will be
  /// -infinity.
  /// @throws std::exception if called pre-finalize.
  VectorX<double> GetPositionLowerLimits() const {
    return internal_tree().GetPositionLowerLimits();
  }

  /// Upper limit analog of GetPositionLowerLimits(), where any unbounded or
  /// unspecified limits will be +infinity.
  /// @see GetPositionLowerLimits() for more information.
  VectorX<double> GetPositionUpperLimits() const {
    return internal_tree().GetPositionUpperLimits();
  }

  /// Returns a vector of size `num_velocities()` containing the lower velocity
  /// limits for every generalized velocity coordinate. These include joint and
  /// free body coordinates. Any unbounded or unspecified limits will be
  /// -infinity.
  /// @throws std::exception if called pre-finalize.
  VectorX<double> GetVelocityLowerLimits() const {
    return internal_tree().GetVelocityLowerLimits();
  }

  /// Upper limit analog of GetVelocitysLowerLimits(), where any unbounded or
  /// unspecified limits will be +infinity.
  /// @see GetVelocityLowerLimits() for more information.
  VectorX<double> GetVelocityUpperLimits() const {
    return internal_tree().GetVelocityUpperLimits();
  }

  /// Returns a vector of size `num_velocities()` containing the lower
  /// acceleration limits for every generalized velocity coordinate. These
  /// include joint and free body coordinates. Any unbounded or unspecified
  /// limits will be -infinity.
  /// @throws std::exception if called pre-finalize.
  VectorX<double> GetAccelerationLowerLimits() const {
    return internal_tree().GetAccelerationLowerLimits();
  }

  /// Upper limit analog of GetAccelerationsLowerLimits(), where any unbounded
  /// or unspecified limits will be +infinity.
  /// @see GetAccelerationLowerLimits() for more information.
  VectorX<double> GetAccelerationUpperLimits() const {
    return internal_tree().GetAccelerationUpperLimits();
  }

  /// Returns a vector of size `num_actuated_dofs()` containing the lower effort
  /// limits for every actuator. Any unbounded or unspecified limits will be
  /// -∞. The returned vector is indexed by @ref JointActuatorIndex, see
  /// JointActuator::index().
  /// @see GetEffortUpperLimits()
  /// @throws std::exception if called pre-finalize.
  VectorX<double> GetEffortLowerLimits() const {
    DRAKE_MBP_THROW_IF_NOT_FINALIZED();
    return internal_tree().GetEffortLowerLimits();
  }

  /// Returns a vector of size `num_actuated_dofs()` containing the upper effort
  /// limits for every actuator. Any unbounded or unspecified limits will be
  /// +∞. The returned vector is indexed by @ref JointActuatorIndex, see
  /// JointActuator::index().
  /// @see GetEffortLowerLimits()
  /// @throws std::exception if called pre-finalize.
  VectorX<double> GetEffortUpperLimits() const {
    DRAKE_MBP_THROW_IF_NOT_FINALIZED();
    return internal_tree().GetEffortUpperLimits();
  }

  /// Returns the model used for contact. See documentation for ContactModel.
  ContactModel get_contact_model() const;

  /// Returns the number of geometries registered for visualization.
  /// This method can be called at any time during the lifetime of `this` plant,
  /// either pre- or post-finalize, see Finalize().
  /// Post-finalize calls will always return the same value.
  int num_visual_geometries() const { return num_visual_geometries_; }

  /// Returns the number of geometries registered for contact modeling.
  /// This method can be called at any time during the lifetime of `this` plant,
  /// either pre- or post-finalize, see Finalize().
  /// Post-finalize calls will always return the same value.
  int num_collision_geometries() const { return num_collision_geometries_; }

  /// Returns the unique id identifying `this` plant as a source for a
  /// SceneGraph.
  /// Returns `nullopt` if `this` plant did not register any geometry.
  /// This method can be called at any time during the lifetime of `this` plant
  /// to query if `this` plant has been registered with a SceneGraph, either
  /// pre- or post-finalize, see Finalize(). However, a geometry::SourceId is
  /// only assigned once at the first call of any of this plant's geometry
  /// registration methods, and it does not change after that.
  /// Post-finalize calls will always return the same value.
  std::optional<geometry::SourceId> get_source_id() const { return source_id_; }

  /// Returns `true` if `this` %MultibodyPlant was registered with a
  /// SceneGraph.
  /// This method can be called at any time during the lifetime of `this` plant
  /// to query if `this` plant has been registered with a SceneGraph, either
  /// pre- or post-finalize, see Finalize().
  bool geometry_source_is_registered() const {
    if (source_id_) {
      if (!is_finalized()) {
        DRAKE_DEMAND(scene_graph_ != nullptr);
      }
      return true;
    } else {
      return false;
    }
  }

  // Note: As discussed in #18351, we've used CamelCase here in case we need to
  // change its implementation down the road to a more expensive lookup.
  /// (Internal use only) Returns a mutable pointer to the SceneGraph that this
  /// plant is registered as a source for. This method can only be used
  /// pre-Finalize.
  ///
  /// @throws std::exception if is_finalized() == true ||
  ///           geometry_source_is_registered() == false
  geometry::SceneGraph<T>* GetMutableSceneGraphPreFinalize() {
    DRAKE_THROW_UNLESS(!is_finalized());
    DRAKE_THROW_UNLESS(geometry_source_is_registered());
    return scene_graph_;
  }

  /// @} <!-- Introspection -->

#ifndef DRAKE_DOXYGEN_CXX
  // Internal-only access to MultibodyGraph::FindSubgraphsOfWeldedBodies();
  // TODO(calderpg-tri) Properly expose this method (docs/tests/bindings).
  std::vector<std::set<BodyIndex>> FindSubgraphsOfWeldedBodies() const;
#endif

  using internal::MultibodyTreeSystem<T>::is_discrete;
  using internal::MultibodyTreeSystem<T>::EvalPositionKinematics;
  using internal::MultibodyTreeSystem<T>::EvalVelocityKinematics;

 private:
  using internal::MultibodyTreeSystem<T>::internal_tree;

  // Allow different specializations to access each other's private data for
  // scalar conversion.
  template <typename U>
  friend class MultibodyPlant;

  // Friend class to facilitate testing.
  friend class MultibodyPlantTester;

  // Friend attorney class to provide private access to those internal::
  // implementations that need it.
  friend class internal::MultibodyPlantModelAttorney<T>;
  friend class internal::MultibodyPlantDiscreteUpdateManagerAttorney<T>;

  // This struct stores in one single place all indexes related to
  // MultibodyPlant specific cache entries. These are initialized at Finalize()
  // when the plant declares its cache entries.
  struct CacheIndexes {
    systems::CacheIndex contact_info_and_body_spatial_forces;
    systems::CacheIndex contact_results;
    systems::CacheIndex contact_surfaces;
    systems::CacheIndex generalized_contact_forces_continuous;
    systems::CacheIndex hydro_fallback;
    systems::CacheIndex point_pairs;
    systems::CacheIndex spatial_contact_forces_continuous;
    systems::CacheIndex discrete_contact_pairs;
    systems::CacheIndex joint_locking_data;
  };

  // This struct stores in one single place all indices related to
  // MultibodyPlant parameters. These are initialized at Finalize()
  // when the plant declares parameters.
  struct ParameterIndices {
    systems::AbstractParameterIndex constraint_active_status;
  };

  // Constructor to bridge testing from MultibodyTree to MultibodyPlant.
  // WARNING: This may *not* result in a plant with a valid state. Use
  // sparingly to test forwarding methods when the overhead is high to
  // reproduce the testing (e.g. benchmarks).
  explicit MultibodyPlant(std::unique_ptr<internal::MultibodyTree<T>> tree_in,
                          double time_step = 0);

  // Helper method for throwing an exception within public methods that should
  // not be called post-finalize. The invoking method should pass its name so
  // that the error message can include that detail.
  void ThrowIfFinalized(const char* source_method) const;

  // Helper method for throwing an exception within public methods that should
  // not be called pre-finalize. The invoking method should pass it's name so
  // that the error message can include that detail.
  void ThrowIfNotFinalized(const char* source_method) const;

  // Helper method that is used to finalize the plant's internals after
  // MultibodyTree::Finalize() was called.
  void FinalizePlantOnly();

  // Consolidates calls to Eval on the geometry query input port to have a
  // consistent and helpful error message in the situation where the
  // geometry_query_input_port is not connected, but is expected to be.
  //
  // Public APIs that ultimately depend on the query object input port should
  // invoke ValidateGeometryInput() to guard against failed access in the depths
  // of the code. As a safety net, all invocations of *this* method should
  // pass the function that invoked it (via __func__), so that if any usage
  // slips through the curated net, some insight will be provided as to what was
  // attempting to access the disconnected port.
  const geometry::QueryObject<T>& EvalGeometryQueryInput(
      const systems::Context<T>& context, std::string_view caller) const;

  // These functions provide a mechanism to provide early warning when a
  // calculation depends on the QueryObject input port. The goal is to provide
  // as much feedback to the caller as to *why* the input port is required.
  // Therefore, it should be called as "high" in the callstack as possible with
  // an explanation of the need (e.g., computing forward dynamics).
  //
  // Note: the connection is only tested if MbP knows about collision
  // geometries. This is correlated with the fact that the operations that
  // depend on the geometry input port only do so based on that same condition.
  void ValidateGeometryInput(const systems::Context<T>& context,
                             std::string_view explanation) const;

  // A validation overload that automatically constructs an explanation when
  // the reason is due to evaluating an output port.
  void ValidateGeometryInput(const systems::Context<T>& context,
                             const systems::OutputPort<T>& output_port) const;

  // Reports if the geometry input is "valid", i.e., either unnecessary or
  // connected.
  bool IsValidGeometryInput(const systems::Context<T>& context) const;

  // Helper to acquire per-geometry contact parameters from SG.
  // Returns the pair (stiffness, dissipation)
  // Defaults to heuristically computed parameter if the given geometry
  // isn't assigned that parameter.
  std::pair<T, T> GetPointContactParameters(
      geometry::GeometryId id,
      const geometry::SceneGraphInspector<T>& inspector) const;

  // Helper to acquire per-geometry Coulomb friction coefficients from
  // SceneGraph.
  const CoulombFriction<double>& GetCoulombFriction(
      geometry::GeometryId id,
      const geometry::SceneGraphInspector<T>& inspector) const;

  // Helper method to apply default collision filters. By default, we don't
  // consider collisions:
  // * between rigid geometries affixed to bodies connected by a joint
  // * within subgraphs of welded-together rigid bodies
  // Note that collisions involving deformable bodies are not filtered by
  // default.
  void ApplyDefaultCollisionFilters();

  // For discrete models, MultibodyPlant uses a penalty method to impose joint
  // limits. In this penalty method a force law of the form:
  //   τ = -k(q - qᵤ) - cv if q > qᵤ
  //   τ = -k(q - qₗ) - cv if q < qₗ
  // is used to limit the position q to be within the lower/upper limits
  // (qₗ, qᵤ).
  // The penalty parameters k (stiffness) and c (damping) are estimated using
  // a harmonic oscillator model of the form ẍ + 2ζω₀ ẋ + ω₀² x = 0, with
  // x = (q - qᵤ) near the upper limit when q > qᵤ and x = (q - qₗ) near the
  // lower limit when q < qₗ and where ω₀² = k / m̃ is the characteristic
  // numerical stiffness frequency and m̃ is an inertia term that for prismatic
  // joints reduces to a simple function of the mass of the bodies adjacent to
  // a particular joint. For revolute joints m̃ relates to the rotational inertia
  // of the adjacent bodies to a joint. See the implementation notes for further
  // details. Both ω₀ and ζ are non-negative numbers.
  // The characteristic frequency ω₀ is entirely a function the time step of the
  // discrete model so that, from a stability analysis of the simplified
  // harmonic oscillator model, we guarantee the resulting time stepping is
  // stable. That is, the numerical stiffness of the method is such that it
  // corresponds to the largest penalty parameter (smaller violation errors)
  // that still guarantees stability.
  void SetUpJointLimitsParameters();

  // Helper method to declare state, cache entries, and ports after Finalize().
  void DeclareStateCacheAndPorts();

  // Declares the system-level cache entries specific to MultibodyPlant.
  void DeclareCacheEntries();

  // Declares the system-level parameters specific to MultibodyPlant.
  void DeclareParameters();

  // Estimates a global set of point contact parameters given a
  // `penetration_allowance`. See set_penetration_allowance()` for details.
  // TODO(amcastro-tri): Once #13064 is resolved, make this a method outside MBP
  // with signature:
  // EstimatePointContactParameters(double penetration_allowance,
  //                                MultibodyPlant<double>* plant)
  // We will document the heuristics used by this method thoroughly so that we
  // have a place we can refer users to for details.
  void EstimatePointContactParameters(double penetration_allowance);

  // Helper method to assemble actuation input vector from the appropriate
  // ports. The return value is indexed by JointActuatorIndex.
  VectorX<T> AssembleActuationInput(const systems::Context<T>& context) const;

  // Computes the total applied actuation through actuators. For continuous
  // models (thus far) this only inludes values coming from the
  // actuation_input_port. For discrete models, it includes actuator
  // controllers, see @ref mbp_actuation. Similarly to AssembleActuationInput(),
  // this function assembles actuation values indexed by JointActuatorIndex.
  void CalcActuationOutput(const systems::Context<T>& context,
                           systems::BasicVector<T>* actuation) const;

  // For models with joint actuators with PD control, this method helps to
  // assemble desired states for the full model from the input ports for
  // individual model instances.
  // The return stacks desired state as xd = [qd, vd], with both qd and vd
  // indexed by JointActuatorIndex (it is assumed that qd.size() == vd.size()).
  VectorX<T> AssembleDesiredStateInput(
      const systems::Context<T>& context) const;

  // Computes all non-contact applied forces including:
  //  - Force elements.
  //  - Joint actuation.
  //  - Externally applied spatial forces.
  //  - Joint limits.
  // @pre The plant is continuous.
  void CalcNonContactForces(const drake::systems::Context<T>& context,
                            MultibodyForces<T>* forces) const;

  // Collects up forces from input ports (actuator, generalized, and spatial
  // forces) and contact forces (from compliant contact models). Does not
  // include ForceElement forces which are accounted for elsewhere.
  void AddInForcesContinuous(const systems::Context<T>& context,
                             MultibodyForces<T>* forces) const override;

  // Discrete system version of CalcForwardDynamics(). This method does not use
  // O(n) forward dynamics but a discrete solver according to the discrete
  // contact solver specified.
  // @see get_discrete_contact_solver().
  void DoCalcForwardDynamicsDiscrete(
      const drake::systems::Context<T>& context,
      internal::AccelerationKinematicsCache<T>* ac) const override;

  // If the plant is modeled as a discrete system with periodic updates (see
  // is_discrete()), this method computes the periodic updates of the state
  // using a semi-explicit Euler strategy, that is:
  //   vⁿ⁺¹ = vⁿ + dt v̇ⁿ
  //   qⁿ⁺¹ = qⁿ + dt N(qⁿ) vⁿ⁺¹
  // This semi-explicit update inherits some of the nice properties of the
  // semi-implicit Euler scheme (which uses v̇ⁿ⁺¹ for the v updated instead) when
  // there are no velocity-dependent forces (including Coriolis and gyroscopic
  // terms). The semi-implicit Euler scheme is a symplectic integrator, which
  // for a Hamiltonian system has the nice property of nearly conserving energy
  // (in many cases we can write a "modified energy functional" which can be
  // shown to be exactly conserved and to be within O(dt) of the real energy of
  // the mechanical system.)
  // TODO(amcastro-tri): Update this docs when contact is added.
  systems::EventStatus CalcDiscreteStep(
      const systems::Context<T>& context0,
      systems::DiscreteValues<T>* updates) const;

  // Data will be resized on output according to the documentation for
  // JointLockingCacheData.
  void CalcJointLockingCache(const systems::Context<T>& context,
                             internal::JointLockingCacheData<T>* data) const;

  // Eval version of the method CalcJointLockingCache().
  const internal::JointLockingCacheData<T>& EvalJointLockingCache(
      const systems::Context<T>& context) const {
    return this->get_cache_entry(cache_indexes_.joint_locking_data)
        .template Eval<internal::JointLockingCacheData<T>>(context);
  }

  // Computes the vector of ContactSurfaces for hydroelastic contact.
  void CalcContactSurfaces(
      const drake::systems::Context<T>& context,
      std::vector<geometry::ContactSurface<T>>* contact_surfaces) const;

  // Eval version of the method CalcContactSurfaces().
  const std::vector<geometry::ContactSurface<T>>& EvalContactSurfaces(
      const systems::Context<T>& context) const {
    // TODO(jwnimmer-tri) This function is too large to be inline.
    // Move its definition to the cc file.
    this->ValidateContext(context);
    switch (contact_model_) {
      case ContactModel::kHydroelasticWithFallback: {
        const auto& data =
            this->get_cache_entry(cache_indexes_.hydro_fallback)
                .template Eval<internal::HydroelasticFallbackCacheData<T>>(
                    context);
        return data.contact_surfaces;
      }
      case ContactModel::kHydroelastic:
        return this->get_cache_entry(cache_indexes_.contact_surfaces)
            .template Eval<std::vector<geometry::ContactSurface<T>>>(context);
      default:
        throw std::logic_error(
            "Attempting to evaluate contact surface for contact model that "
            "doesn't use it");
    }
  }

  // Computes the hydroelastic fallback method -- all contacts are partitioned
  // between ContactSurfaces and point pair contacts.
  void CalcHydroelasticWithFallback(
      const drake::systems::Context<T>& context,
      internal::HydroelasticFallbackCacheData<T>* data) const;

  // Helper method to fill in the ContactResults given the current context when
  // the model is continuous.
  // @param[out] contact_results is fully overwritten
  void CalcContactResultsContinuous(const systems::Context<T>& context,
                                    ContactResults<T>* contact_results) const;

  // Helper method for the continuous mode plant, to fill in the ContactResults
  // for the point pair model, given the current context. Called by
  // CalcContactResultsContinuous.
  // @param[in,out] contact_results is appended to
  void AppendContactResultsContinuousPointPair(
      const systems::Context<T>& context,
      ContactResults<T>* contact_results) const;

  // Helper method to fill in `contact_results` with hydroelastic forces as a
  // function of the state stored in `context`.
  // @param[in,out] contact_results is appended to
  void AppendContactResultsContinuousHydroelastic(
      const systems::Context<T>& context,
      ContactResults<T>* contact_results) const;

  // Evaluate contact results.
  const ContactResults<T>& EvalContactResults(
      const systems::Context<T>& context) const {
    if (this->is_discrete()) {
      return discrete_update_manager_->EvalContactResults(context);
    } else {
      return this->get_cache_entry(cache_indexes_.contact_results)
          .template Eval<ContactResults<T>>(context);
    }
  }

  // Calc method for the reaction forces output port.
  // A joint constraints the motion between a frame Jp on a "parent" P and a
  // frame Jc on a "child" frame C. This generates reaction forces on bodies P
  // and C in order to satisfy the kinematic constraint between Jp and Jc. This
  // method computes the spatial force F_CJc_Jc on body C at frame Jc and
  // expressed in frame Jc. See get_reaction_forces_output_port() for further
  // details.
  void CalcReactionForces(const systems::Context<T>& context,
                          std::vector<SpatialForce<T>>* F_CJc_Jc) const;

  // Collect joint actuator forces and externally provided spatial and
  // generalized forces.
  void AddInForcesFromInputPorts(const drake::systems::Context<T>& context,
                                 MultibodyForces<T>* forces) const;

  // Add contribution of generalized forces passed in through our
  // applied_generalized_force input port.
  void AddAppliedExternalGeneralizedForces(const systems::Context<T>& context,
                                           MultibodyForces<T>* forces) const;

  // Add contribution of body spatial forces passed in through our
  // applied_spatial_force input port.
  void AddAppliedExternalSpatialForces(const systems::Context<T>& context,
                                       MultibodyForces<T>* forces) const;

  // Add contribution of external actuation forces passed in through our
  // actuation input ports (there is a separate port for each model instance).
  void AddJointActuationForces(const systems::Context<T>& context,
                               VectorX<T>* forces) const;

  // Helper method to register geometry for a given body, either visual or
  // collision. The registration includes:
  // 1. Register geometry for the corresponding FrameId associated with `body`.
  // 2. Update the geometry_id_to_body_index_ map associating the new GeometryId
  //    to the BodyIndex of `body`.
  // This assumes:
  // 1. Finalize() was not called on `this` plant.
  // 2. RegisterAsSourceForSceneGraph() was called on `this` plant.
  // 3. `scene_graph` points to the same SceneGraph instance previously
  //    passed to RegisterAsSourceForSceneGraph().
  geometry::GeometryId RegisterGeometry(
      const Body<T>& body, const math::RigidTransform<double>& X_BG,
      const geometry::Shape& shape, const std::string& name);

  // Registers a geometry frame for every body. If the body already has a
  // geometry frame, it is unchanged. This registration is part of finalization.
  // This requires RegisterAsSourceForSceneGraph() was called on `this` plant.
  void RegisterGeometryFramesForAllBodies();

  bool body_has_registered_frame(const Body<T>& body) const {
    return body_index_to_frame_id_.find(body.index()) !=
           body_index_to_frame_id_.end();
  }

  // Registers the given body with this plant's SceneGraph instance (if it has
  // one).
  void RegisterRigidBodyWithSceneGraph(const Body<T>& body);

  // Calc method for the multibody state vector output port. It only copies the
  // multibody state [q, v], ignoring any miscellaneous state z if present.
  void CopyMultibodyStateOut(const systems::Context<T>& context,
                             systems::BasicVector<T>* state) const;

  // Calc method for the per-model-instance multibody state vector output port.
  // It only copies the per-model-instance multibody state [q, v], ignoring any
  // miscellaneous state z if present.
  void CopyMultibodyStateOut(ModelInstanceIndex model_instance,
                             const systems::Context<T>& context,
                             systems::BasicVector<T>* state) const;

  // Evaluates the pose X_WB of each body in the model and copies it into
  // X_WB_all, indexed by BodyIndex.
  void CalcBodyPosesOutput(
      const systems::Context<T>& context,
      std::vector<math::RigidTransform<T>>* X_WB_all) const;

  // Evaluates the spatial velocity V_WB of each body in the model and copies it
  // into V_WB_all, indexed by BodyIndex.
  void CalcBodySpatialVelocitiesOutput(
      const systems::Context<T>& context,
      std::vector<SpatialVelocity<T>>* V_WB_all) const;

  // For each body B in the model, evaluates A_WB, B's spatial acceleration
  // in the world frame W, expressed in W (for point Bo, the body's origin) and
  // copies it into A_WB_all, indexed by BodyIndex.
  void CalcBodySpatialAccelerationsOutput(
      const systems::Context<T>& context,
      std::vector<SpatialAcceleration<T>>* A_WB_all) const;

  // Method to compute spatial contact forces for continuous plants.
  // @note This version zeros out the forces in @p F_BBo_W_array before adding
  // in contact force.
  // @see CalcAndAddSpatialContactForcesContinuous() for the version of this
  // method that does not zero out the forces.
  void CalcSpatialContactForcesContinuous(
      const drake::systems::Context<T>& context,
      std::vector<SpatialForce<T>>* F_BBo_W_array) const;

  // Method to compute spatial contact forces for continuous plants.
  // @note This version does *not* zero out the forces in @p F_BBo_W_array.
  // @see CalcSpatialContactForcesContinuous() for the version of this method
  // that zeros out @p F_BBo_W_array before adding in contact forces.
  void CalcAndAddSpatialContactForcesContinuous(
      const drake::systems::Context<T>& context,
      std::vector<SpatialForce<T>>* F_BBo_W_array) const;

  // Eval() version of the method CalcSpatialContactForcesContinuous().
  const std::vector<SpatialForce<T>>& EvalSpatialContactForcesContinuous(
      const systems::Context<T>& context) const {
    return this
        ->get_cache_entry(cache_indexes_.spatial_contact_forces_continuous)
        .template Eval<std::vector<SpatialForce<T>>>(context);
  }

  // Method to compute generalized contact forces for continuous plants.
  void CalcGeneralizedContactForcesContinuous(
      const drake::systems::Context<T>& context, VectorX<T>* tau_contact) const;

  // Eval() version of the method CalcGeneralizedContactForcesContinuous().
  const VectorX<T>& EvalGeneralizedContactForcesContinuous(
      const systems::Context<T>& context) const {
    return this
        ->get_cache_entry(cache_indexes_.generalized_contact_forces_continuous)
        .template Eval<VectorX<T>>(context);
  }

  // Calc method to output per model instance vector of generalized contact
  // forces.
  void CopyGeneralizedContactForcesOut(
      const contact_solvers::internal::ContactSolverResults<T>&,
      ModelInstanceIndex, systems::BasicVector<T>* tau_vector) const;

  // Helper method to declare output ports used by this plant to communicate
  // with a SceneGraph.
  void DeclareSceneGraphPorts();

  void CalcFramePoseOutput(const systems::Context<T>& context,
                           geometry::FramePoseVector<T>* poses) const;

  void CopyContactResultsOutput(const systems::Context<T>& context,
                                ContactResults<T>* contact_results) const;

  // Helper method to compute penetration point pairs for a given `context`.
  // Having this as a separate method allows us to control specializations for
  // different scalar types.
  void CalcPointPairPenetrations(
      const systems::Context<T>& context,
      std::vector<geometry::PenetrationAsPointPair<T>>*) const;

  // (Advanced) Helper method to compute contact forces in the normal direction
  // using a penalty method.
  void CalcAndAddContactForcesByPenaltyMethod(
      const systems::Context<T>& context,
      std::vector<SpatialForce<T>>* F_BBo_W_array) const;

  // Helper method to compute contact forces using the hydroelastic model.
  // F_BBo_W_array is indexed by BodyNodeIndex and it gets overwritten on
  // output. F_BBo_W_array must be of size num_bodies() or an exception is
  // thrown.
  void CalcHydroelasticContactForces(
      const systems::Context<T>& context,
      internal::HydroelasticContactInfoAndBodySpatialForces<T>* F_BBo_W_array)
      const;

  // Eval version of CalcHydroelasticContactForces().
  const internal::HydroelasticContactInfoAndBodySpatialForces<T>&
  EvalHydroelasticContactForces(const systems::Context<T>& context) const {
    return this
        ->get_cache_entry(cache_indexes_.contact_info_and_body_spatial_forces)
        .template Eval<
            internal::HydroelasticContactInfoAndBodySpatialForces<T>>(context);
  }

  // Helper method to apply penalty forces that enforce joint limits.
  // At each joint with joint limits this penalty method applies a force law of
  // the form:
  //   τ = min(-k(q - qᵤ) - cv, 0) if q > qᵤ
  //   τ = max(-k(q - qₗ) - cv, 0) if q < qₗ
  // is used to limit the position q to be within the lower/upper limits
  // (qₗ, qᵤ).
  // The penalty parameters k (stiffness) and c (damping) are estimated using
  // a harmonic oscillator model within SetUpJointLimitsParameters().
  void AddJointLimitsPenaltyForces(const systems::Context<T>& context,
                                   MultibodyForces<T>* forces) const;

  // Given a GeometryId, return the corresponding BodyIndex or throw if the
  // GeometryId is invalid or unknown to this plant.
  BodyIndex FindBodyByGeometryId(geometry::GeometryId) const;

  // Gets the parameter corresponding to constraint active status.
  const std::map<MultibodyConstraintId, bool>& GetConstraintActiveStatus(
      const systems::Context<T>& context) const {
    return context.get_parameters()
        .template get_abstract_parameter<internal::ConstraintActiveStatusMap>(
            parameter_indices_.constraint_active_status)
        .map;
  }

  // Gets the mutable parameter corresponding to constraint active status.
  std::map<MultibodyConstraintId, bool>& GetMutableConstraintActiveStatus(
      systems::Context<T>* context) const {
    return context->get_mutable_parameters()
        .template get_mutable_abstract_parameter<
            internal::ConstraintActiveStatusMap>(
            parameter_indices_.constraint_active_status)
        .map;
  }

  // Removes `this` MultibodyPlant's ability to convert to the scalar types
  // unsupported by the given `component`.
  void RemoveUnsupportedScalars(
      const internal::ScalarConvertibleComponent<T>& component);

  // Geometry source identifier for this system to interact with geometry
  // system. It is made optional for plants that do not register geometry
  // (dynamics only).
  std::optional<geometry::SourceId> source_id_{std::nullopt};

  internal::ContactByPenaltyMethodParameters penalty_method_contact_parameters_;

  // Penetration allowance used to estimate ContactByPenaltyMethodParameters.
  // See set_penetration_allowance() for details.
  double penetration_allowance_{MultibodyPlantConfig{}.penetration_allowance};

  // Stribeck model of friction.
  class StribeckModel {
   public:
    DRAKE_DEFAULT_COPY_AND_MOVE_AND_ASSIGN(StribeckModel)

    /// Creates an uninitialized Stribeck model with an invalid value (negative)
    /// of the stiction tolerance.
    StribeckModel() = default;

    /// Computes the friction coefficient based on the tangential *speed*
    /// `speed_BcAc` of the contact point `Ac` on A relative to the
    /// contact point `Bc` on B. That is, `speed_BcAc = ‖vt_BcAc‖`, where
    /// `vt_BcAc` is the tangential component of the velocity `v_BcAc` of
    /// contact point `Ac` relative to point `Bc`.
    ///
    /// See contact_model_doxygen.h @section tangent_force for details.
    T ComputeFrictionCoefficient(const T& speed_BcAc,
                                 const CoulombFriction<double>& friction) const;

    /// Evaluates an S-shaped quintic curve, f(x), mapping the domain [0, 1] to
    /// the range [0, 1] where f(0) = f''(0) = f''(1) = f'(0) = f'(1) = 0 and
    /// f(1) = 1.
    static T step5(const T& x);

    /// Sets the stiction tolerance `v_stiction` for the Stribeck model, where
    /// `v_stiction` must be specified in m/s (meters per second.)
    /// @throws std::exception if `v_stiction` is non-positive.
    void set_stiction_tolerance(double v_stiction) {
      DRAKE_THROW_UNLESS(v_stiction > 0);
      v_stiction_tolerance_ = v_stiction;
      inv_v_stiction_tolerance_ = 1.0 / v_stiction;
    }

    /// Returns the value of the stiction tolerance for `this` %MultibodyPlant.
    /// It returns a negative value when the stiction tolerance has not been set
    /// previously with set_stiction_tolerance().
    double stiction_tolerance() const { return v_stiction_tolerance_; }

   private:
    // Stiction velocity tolerance for the Stribeck model.
    double v_stiction_tolerance_{MultibodyPlantConfig{}.stiction_tolerance};
    // Note: this is the *inverse* of the v_stiction_tolerance_ parameter to
    // optimize for the division.
    double inv_v_stiction_tolerance_{1.0 / v_stiction_tolerance_};
  };
  StribeckModel friction_model_;

  // This structure aids in the bookkeeping of parameters associated with joint
  // limits and the penalty method parameters used to enforce them.
  struct JointLimitsParameters {
    // list of joints that have limits. These are all single-dof joints.
    std::vector<JointIndex> joints_with_limits;
    // Position lower/upper bounds for each joint in joints_with_limits. The
    // Units depend on the particular joint type. For instance, radians for
    // RevoluteJoint or meters for PrismaticJoint.
    std::vector<double> lower_limit;
    std::vector<double> upper_limit;
    // Penalty parameters. These are defined in accordance to the penalty force
    // internally implemented by MultibodyPlant in
    // AddJointLimitsPenaltyForces().
    std::vector<double> stiffness;
    std::vector<double> damping;
    // If these joint limits will be ignored (because the plant uses continuous
    // time) and we have not yet warned the user about that fact, this contains
    // the warning message to be printed. Marked mutable because it's not part
    // of our dynamics, so that we can clear it from a const method.
    mutable std::string pending_warning_message;
  } joint_limits_parameters_;

  // Iteration order on this map DOES matter, and therefore we use an std::map.
  std::map<BodyIndex, geometry::FrameId> body_index_to_frame_id_;

  // Data to get back from a SceneGraph-reported frame id to its associated
  // body.
  std::unordered_map<geometry::FrameId, BodyIndex> frame_id_to_body_index_;

  // Map from GeometryId to BodyIndex. During contact queries, it allows to find
  // out to which body a given geometry corresponds to.
  std::unordered_map<geometry::GeometryId, BodyIndex>
      geometry_id_to_body_index_;

  // Per-body arrays of visual geometries indexed by BodyIndex.
  // That is, visual_geometries_[body_index] corresponds to the array of visual
  // geometries for body with index body_index.
  std::vector<std::vector<geometry::GeometryId>> visual_geometries_;

  // The total number of GeometryId values within visual_geometries_.
  int num_visual_geometries_{0};

  // Per-body arrays of collision geometries indexed by BodyIndex.
  // That is, collision_geometries_[body_index] corresponds to the array of
  // collision geometries for body with index body_index.
  std::vector<std::vector<geometry::GeometryId>> collision_geometries_;

  // The total number of GeometryId values within collision_geometries_.
  int num_collision_geometries_{0};

  // The model used by the plant to compute contact forces. Keep this in sync
  // with the default value in multibody_plant_config.h; there are already
  // assertions in the cc file that enforce this.
  ContactModel contact_model_{ContactModel::kHydroelasticWithFallback};

  // The solver type used by a discrete plant. Keep this in sync
  // with the default value in multibody_plant_config.h; there are already
  // assertions in the cc file that enforce this.
  DiscreteContactSolver contact_solver_enum_{DiscreteContactSolver::kTamsi};

  // Near rigid regime parameter from [Castro et al., 2021]. Refer to
  // set_near_rigid_threshold() for details.
  double sap_near_rigid_threshold_{
      MultibodyPlantConfig{}.sap_near_rigid_threshold};

  // User's choice of the representation of contact surfaces in discrete
  // systems. The default value is dependent on whether the system is
  // continuous or discrete, so the constructor will set it. See
  // GetDefaultContactSurfaceRepresentation().
  geometry::HydroelasticContactRepresentation contact_surface_representation_{};

  // Port handles for geometry:
  systems::InputPortIndex geometry_query_port_;
  systems::OutputPortIndex geometry_pose_port_;

  // For geometry registration with a GS, we save a pointer to the GS instance
  // on which this plants calls RegisterAsSourceForSceneGraph(). This will be
  // set to `nullptr` after finalization, to mirror constraints presented by
  // scalar conversion (where we cannot easily obtain a reference to the
  // scalar-converted scene graph).
  geometry::SceneGraph<T>* scene_graph_{nullptr};

  // Input/Output port indexes:

  // A vector containing actuation ports for each model instance indexed by
  // ModelInstanceIndex. Every model instance has a corresponding port even
  // if that instance has no actuators.
  std::vector<systems::InputPortIndex> instance_actuation_ports_;

  // The actuation input port for all actuated dofs.
  systems::InputPortIndex actuation_port_;

  // Net actuation applied through actuators.
  systems::OutputPortIndex net_actuation_port_;

  std::vector<systems::InputPortIndex> instance_desired_state_ports_;

  // A port for externally applied generalized forces u.
  systems::InputPortIndex applied_generalized_force_input_port_;

  // Port for externally applied spatial forces F.
  systems::InputPortIndex applied_spatial_force_input_port_;

  // Ports for spatial kinematics.
  systems::OutputPortIndex body_poses_port_;
  systems::OutputPortIndex body_spatial_velocities_port_;
  systems::OutputPortIndex body_spatial_accelerations_port_;

  // A port presenting state x=[q v] for the whole system, and a vector of
  // ports presenting state subsets xᵢ=[qᵢ vᵢ] ⊆ x for each model instance i,
  // indexed by ModelInstanceIndex. Every model instance has a corresponding
  // port even if it has no states.
  systems::OutputPortIndex state_output_port_;
  std::vector<systems::OutputPortIndex> instance_state_output_ports_;

  // A port presenting generalized accelerations v̇ for the whole system, and
  // a vector of ports presenting acceleration subsets v̇ᵢ ⊆ v̇ for each model
  // instance i, indexed by ModelInstanceIndex. Every model instance has a
  // corresponding port even if it has no states.
  systems::OutputPortIndex generalized_acceleration_output_port_;
  std::vector<systems::OutputPortIndex>
      instance_generalized_acceleration_output_ports_;

  // Index for the output port of ContactResults.
  systems::OutputPortIndex contact_results_port_;

  // Joint reactions forces port index.
  systems::OutputPortIndex reaction_forces_port_;

  // A vector containing the index for the generalized contact forces port for
  // each model instance. This vector is indexed by ModelInstanceIndex. An
  // invalid value indicates that the model instance has no generalized
  // velocities and thus no generalized forces.
  std::vector<systems::OutputPortIndex>
      instance_generalized_contact_forces_output_ports_;

  // If the plant is modeled as a discrete system with periodic updates,
  // time_step_ corresponds to the period of those updates. Otherwise, if the
  // plant is modeled as a continuous system, it is exactly zero.
  double time_step_{0};

  // When not the nullptr, this manager class is used to advance discrete
  // states.
  // TODO(amcastro-tri): migrate the entirety of computations related to contact
  // resolution into a default contact manager.
  std::unique_ptr<internal::DiscreteUpdateManager<T>> discrete_update_manager_;

  // (Experimental) The vector of physical models owned by MultibodyPlant.
  std::vector<std::unique_ptr<PhysicalModel<T>>> physical_models_;

  // Map of coupler constraints specifications.
  std::map<MultibodyConstraintId, internal::CouplerConstraintSpec>
      coupler_constraints_specs_;

  // Map of distance constraints specifications.
  std::map<MultibodyConstraintId, internal::DistanceConstraintSpec>
      distance_constraints_specs_;

  // Map of ball constraint specifications.
  std::map<MultibodyConstraintId, internal::BallConstraintSpec>
      ball_constraints_specs_;

  // Map of weld constraint specifications.
  std::map<MultibodyConstraintId, internal::WeldConstraintSpec>
      weld_constraints_specs_;

  // All MultibodyPlant cache indexes are stored in cache_indexes_.
  CacheIndexes cache_indexes_;

  // All MultibodyPlant parameter indices are stored in parameter_indices_.
  ParameterIndices parameter_indices_;

  // Whether to apply collsion filters to adjacent bodies at Finalize().
  bool adjacent_bodies_collision_filters_{
      MultibodyPlantConfig{}.adjacent_bodies_collision_filters};
};

/// @cond
// Undef macros defined at the top of the file. From the GSG:
// "Exporting macros from headers (i.e. defining them in a header without
// #undefing them before the end of the header) is extremely strongly
// discouraged."
// This will require us to re-define them in the .cc file.
#undef DRAKE_MBP_THROW_IF_FINALIZED
#undef DRAKE_MBP_THROW_IF_NOT_FINALIZED
/// @endcond

// Forward declare to permit exclusive friendship for construction.
template <typename T>
struct AddMultibodyPlantSceneGraphResult;

/// Makes a new MultibodyPlant with discrete update period `time_step` and
/// adds it to a diagram builder together with the provided SceneGraph instance,
/// connecting the geometry ports.
/// @note Usage examples in @ref add_multibody_plant_scene_graph
/// "AddMultibodyPlantSceneGraph".
///
/// @param[in,out] builder
///   Builder to add to.
/// @param[in] time_step
///   The discrete update period for the new MultibodyPlant to be added.
///   Please refer to the documentation provided in
///   MultibodyPlant::MultibodyPlant(double) for further details on the
///   parameter `time_step`.
/// @param[in] scene_graph (optional)
///   Constructed scene graph. If none is provided, one will be created and
///   used.
/// @return Pair of the registered plant and scene graph.
/// @pre `builder` must be non-null.
/// @tparam_default_scalar
/// @relates MultibodyPlant
template <typename T>
AddMultibodyPlantSceneGraphResult<T> AddMultibodyPlantSceneGraph(
    systems::DiagramBuilder<T>* builder, double time_step,
    std::unique_ptr<geometry::SceneGraph<T>> scene_graph = nullptr);

/// Adds a MultibodyPlant and a SceneGraph instance to a diagram
/// builder, connecting the geometry ports.
/// @note Usage examples in @ref add_multibody_plant_scene_graph
/// "AddMultibodyPlantSceneGraph".
///
/// @param[in,out] builder
///   Builder to add to.
/// @param[in] plant
///   Plant to be added to the builder.
/// @param[in] scene_graph (optional)
///   Constructed scene graph. If none is provided, one will be created and
///   used.
/// @return Pair of the registered plant and scene graph.
/// @pre `builder` and `plant` must be non-null.
/// @tparam_default_scalar
/// @relates MultibodyPlant
template <typename T>
AddMultibodyPlantSceneGraphResult<T> AddMultibodyPlantSceneGraph(
    systems::DiagramBuilder<T>* builder,
    std::unique_ptr<MultibodyPlant<T>> plant,
    std::unique_ptr<geometry::SceneGraph<T>> scene_graph = nullptr);

/// Temporary result from `AddMultibodyPlantSceneGraph`. This cannot be
/// constructed outside of this method.
/// @warning Do NOT use this as a function argument or member variable. The
/// lifetime of this object should be as short as possible.
/// @tparam_default_scalar
template <typename T>
struct AddMultibodyPlantSceneGraphResult final {
  MultibodyPlant<T>& plant;
  geometry::SceneGraph<T>& scene_graph;

  /// For assignment to a plant reference (ignoring the scene graph).
  operator MultibodyPlant<T>&() { return plant; }

  /// For assignment to a std::tie of pointers.
  operator std::tuple<MultibodyPlant<T>*&, geometry::SceneGraph<T>*&>() {
    return std::tie(plant_ptr, scene_graph_ptr);
  }

#ifndef DRAKE_DOXYGEN_CXX
  // Returns the N-th member referenced by this struct.
  // If N = 0, returns the reference to the MultibodyPlant.
  // If N = 1, returns the reference to the geometry::SceneGraph.
  // Provided to support C++17's structured binding.
  template <std::size_t N>
  decltype(auto) get() const {
    if constexpr (N == 0)
      return plant;
    else if constexpr (N == 1)
      return scene_graph;
  }
#endif

#ifndef DRAKE_DOXYGEN_CXX
  // Only the move constructor is enabled; copy/assign/move-assign are deleted.
  AddMultibodyPlantSceneGraphResult(AddMultibodyPlantSceneGraphResult&&) =
      default;
  AddMultibodyPlantSceneGraphResult(const AddMultibodyPlantSceneGraphResult&) =
      delete;
  void operator=(const AddMultibodyPlantSceneGraphResult&) = delete;
  void operator=(AddMultibodyPlantSceneGraphResult&&) = delete;
#endif

 private:
  // Deter external usage by hiding construction.
  friend AddMultibodyPlantSceneGraphResult AddMultibodyPlantSceneGraph<T>(
      systems::DiagramBuilder<T>*, std::unique_ptr<MultibodyPlant<T>>,
      std::unique_ptr<geometry::SceneGraph<T>>);

  AddMultibodyPlantSceneGraphResult(MultibodyPlant<T>* plant_in,
                                    geometry::SceneGraph<T>* scene_graph_in)
      : plant(*plant_in),
        scene_graph(*scene_graph_in),
        plant_ptr(plant_in),
        scene_graph_ptr(scene_graph_in) {}

  // Pointers to enable implicit casts for `std::tie()` assignments using
  // `T*&`.
  MultibodyPlant<T>* plant_ptr{};
  geometry::SceneGraph<T>* scene_graph_ptr{};
};

namespace internal {
// Combines the contact stiffness and dissipation parameters from two bodies in
// contact to create the contact stiffness and dissipation to be used for the
// contact pair.
// @tparam_default_scalar
template <typename T>
std::pair<T, T> CombinePointContactParameters(const T& k1, const T& k2,
                                              const T& d1, const T& d2) {
  // Simple utility to detect 0 / 0. As it is used in this method, denom
  // can only be zero if num is also zero, so we'll simply return zero.
  auto safe_divide = [](const T& num, const T& denom) {
    return denom == 0.0 ? 0.0 : num / denom;
  };
  return std::pair(
      safe_divide(k1 * k2, k1 + k2),                                   // k
      safe_divide(k2, k1 + k2) * d1 + safe_divide(k1, k1 + k2) * d2);  // d
}
}  // namespace internal

#ifndef DRAKE_DOXYGEN_CXX
// Forward-declare specializations, prior to DRAKE_DECLARE... below.
// See the .cc file for an explanation why we specialize these methods.
template <>
void MultibodyPlant<symbolic::Expression>::CalcHydroelasticContactForces(
    const systems::Context<symbolic::Expression>&,
    internal::HydroelasticContactInfoAndBodySpatialForces<
        symbolic::Expression>*) const;
template <>
void MultibodyPlant<symbolic::Expression>::
    AppendContactResultsContinuousHydroelastic(
        const systems::Context<symbolic::Expression>&,
        ContactResults<symbolic::Expression>*) const;
template <>
void MultibodyPlant<symbolic::Expression>::CalcContactSurfaces(
    const systems::Context<symbolic::Expression>&,
    std::vector<geometry::ContactSurface<symbolic::Expression>>*) const;
template <>
void MultibodyPlant<symbolic::Expression>::CalcHydroelasticWithFallback(
    const systems::Context<symbolic::Expression>&,
    internal::HydroelasticFallbackCacheData<symbolic::Expression>*) const;
#endif

}  // namespace multibody
}  // namespace drake

#ifndef DRAKE_DOXYGEN_CXX
// Specializations provided to support C++17's structured binding for
// AddMultibodyPlantSceneGraphResult.
namespace std {
// The GCC standard library defines tuple_size as class and struct which
// triggers a warning here.
// We found this solution in: https://github.com/nlohmann/json/issues/1401
#if defined(__clang__)
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wmismatched-tags"
#endif
template <typename T>
struct tuple_size<drake::multibody::AddMultibodyPlantSceneGraphResult<T>>
    : std::integral_constant<std::size_t, 2> {};

template <typename T>
struct tuple_element<0,
                     drake::multibody::AddMultibodyPlantSceneGraphResult<T>> {
  using type = drake::multibody::MultibodyPlant<T>;
};

template <typename T>
struct tuple_element<1,
                     drake::multibody::AddMultibodyPlantSceneGraphResult<T>> {
  using type = drake::geometry::SceneGraph<T>;
};
#if defined(__clang__)
#pragma GCC diagnostic pop
#endif
}  // namespace std
#endif

DRAKE_DECLARE_CLASS_TEMPLATE_INSTANTIATIONS_ON_DEFAULT_SCALARS(
    class drake::multibody::MultibodyPlant)
DRAKE_DECLARE_CLASS_TEMPLATE_INSTANTIATIONS_ON_DEFAULT_SCALARS(
    struct drake::multibody::AddMultibodyPlantSceneGraphResult)
